A Photon‐Fueled Gate‐Like Delivery System Using i‐Motif DNA Functionalized Mesoporous Silica Nanoparticles

A novel photon‐fueled gate‐like mesoporous silica nanoparticles (MSN)‐based delivery system is reported. In this system, the malachite green carbinol base (MGCB) is immobilized on the nanochannel wall of MSN as a light‐induced hydroxide ion emitter and i‐motif DNA is grafted on the surface of MSN as a cap. Photoirradiation with 365 nm wavelength UV light makes MGCB molecules dissociate into malachite green (MG) cations and OH^? ions, which induce the i‐motif DNA to unfold into the single‐stranded form due to the increase of the pH in the solution. Therefore, the pores are uncapped and the entrapped guest molecules are released. After the light is turned off, the MG cations recombine with the OH^? ions and return to the MGCB forms. The pH value thus decreases and the single‐stranded DNA switches back to i‐motif structure to cap the pore again. Because of the photon‐fueled MGCB‐dependent DNA conformation changes, the i‐motif DNA‐gated switch can be easily operated by turning the light on or off. Importantly, the opening/closing protocol is highly reversible and a partial cargo release can be easily achieved at will. This proof‐of‐concept may promote the application of DNA in the controlled release and can also provide a way to design various photon‐fueled controlled‐release systems using a combination of some photoirradiated pH‐jump systems and other kinds of pH‐sensitive linkers.     

A Triple‐Collaborative Strategy for High‐Performance Tumor Therapy by Multifunctional Mesoporous Silica‐Coated Gold Nanorods

To integrate treatments of photothermal therapy, photodynamic therapy (PDT), and chemotherapy, this study reports on a multifunctional nanocomposite based on mesoporous silica‐coated gold nanorod for high‐performance oncotherapy. Gold nanorod core is used as the hyperthermal agent and mesoporous silica shell is used as the reservoir of photosensitizer (Al(III) phthalocyanine chloride tetrasulfonic acid, AlPcS₄). The mesoporous silica shell is modified with β‐cyclodextrin (β‐CD) gatekeeper via redox‐cleavable Pt(IV) complex for controlled drug release. Furthermore, tumor targeting ligand (lactobionic acid, LA) and long‐circulating poly(ethylene glycol) chain are introduced via host–guest interaction. It is found that the nanocomposite can specifically target to hepatoma cells by virtue of the LA targeting moiety. Due to the abundant existence of reducing agents within tumor cells, β‐CD can be removed by reducing the Pt(IV) complex to active cisplatin drug for chemotherapy, along with the releasing of entrapped AlPcS₄ for effective PDT. As confirmed by in vitro and in vivo studies, the nanocomposite exhibits an obvious near‐infrared induced thermal effect, which significantly improves the PDT and chemotherapy efficiency, resulting in a superadditive therapeutic effect. This collaborative strategy paves the way toward high‐performance nanotherapeutics with a superior antitumor efficacy and much reduced side effects.     

Gold Core‐DNA‐Silver Shell Nanoparticles with Intense Plasmonic Chiroptical Activities

The strong plasmonic chiroptical activities of gold core‐DNA‐silver shell nanoparticles (NPs) are reported for the first time, using cytosine‐rich single‐stranded DNA as the template for the guidance of silver shell growth. The anisotropy factor of the optically active NPs at 420 nm reaches 1.93 × 10^?2. Their chiroptical properties are likely induced by the DNA–plasmon interaction and markedly amplified by the strong electromagnetic coupling between the gold core and silver shell.     

Folic‐Acid‐Mediated Functionalized Gold Nanocages for Targeted Delivery of Anti‐miR‐181b in Combination of Gene Therapy and Photothermal Therapy against Hepatocellular Carcinoma

Therapeutic strategies based on modulation of microRNAs (miRNAs) activity hold much promise for cancer therapy, but for clinical applications, the efficient delivery of miRNAs to tumor cells or tumor tissues remains a great challenge. In this work, microRNA‐181b inhibitor (anti‐miR‐181b) is successfully condensed into polyethyleneimine (PEI)‐modified and folate receptor (FR)‐targeted PEGylated gold nanocages (AuNCs). This delivery system is designated as anti‐miR‐181b/PTPAuNCs nanocomplexes (PTPAuNC‐NPs), which begin with chemical modification of AuNCs with SH‐PEG₅₀₀₀‐folic acid (SH‐PEG₅₀₀₀‐FA) and SH‐PEG₅₀₀₀ through a gold–sulfur bond, followed by conjugating PEI using lipoic acid as a linker. Finally anti‐miR‐181b is condensed via electrostatic interactions. In vitro and in vivo experiments show that PTPAuNC‐NPs can efficiently deliver anti‐miR‐181b into target sites to suppress tumor growth, and considerably decrease tumor volumes in SMMC‐7721 tumor‐bearing nude mice under near‐infrared radiation. All these results suggest that PTPAuNC‐NP gene delivery system with combination of gene therapy and photothermal therapy will be of great potential use in future cancer therapy.     

Gold Nanoframeworks with Mesopores for Raman–Photoacoustic Imaging and Photo‐Chemo Tumor Therapy in the Second Near‐Infrared Biowindow

Gold‐based nanostructures with tunable wavelength of localized surface plasmon resonance (LSPR) in the second near‐infrared (NIR‐II) biowindow receive increasing attention in phototheranostics. In view of limited progress on NIR‐II gold nanostructures, a particular liposome template‐guided route is explored to synthesize novel gold nanoframeworks (AuNFs) with large mesopores (≈40 nm) for multimodal imaging along with therapeutic robustness. The synthesized AuNFs exhibit strong absorbance in NIR‐II region, affording their capacity of NIR‐II photothermal therapy (PTT) and photoacoustic (PA) imaging for deep tumors. Functionalization of AuNFs with hyaluronic acid (HA) endows the targeting capacity for CD44‐overexpressed tumor cells while gatekeeping doxorubicin (DOX) loaded into mesopores. Conjugation of Raman reporter 4‐aminothiophenol (4‐ATP) onto AuNFs yields a surface‐enhanced Raman scattering (SERS) fingerprint for Raman spectroscopy/imaging. In vivo evaluation of HA‐4‐ATP‐AuNFs‐DOX on tumor‐bearing xenografts demonstrates its high efficacy in eradication of solid tumors in NIR‐II under PA–Raman dual image‐guided photo‐chemotherapy. Thus, current AuNFs offer versatile capabilities for phototheranostics.     

Combination of Bacterial‐Photothermal Therapy with an Anti‐PD‐1 Peptide Depot for Enhanced Immunity against Advanced Cancer

Photothermal therapy (PTT) is a promising cancer treatment, but it has so far proven successful only with relatively small subcutaneous tumors in animal models. Treating larger tumors (≈200 mm³) is challenging because most PTT materials do not efficiently reach the hypoxic, avascular center of tumors, and the immunosuppressive tumor microenvironment prevents T cells from fighting against residual tumor cells, thereby allowing recurrence and metastasis. Here, the widely used PTT material polydopamine is coated on the surface of the facultative anaerobe Salmonella VNP20009, which can penetrate deep into larger tumors. The coated bacteria are intravenously injected followed by near‐infrared laser irradiation at the tumor site, combined with a local inoculation of phospholipid‐based phase separation gel containing the anti‐programmed cell death‐1 peptide AUNP‐12. The gel releases AUNP‐12 sustainably during 42 days, maintaining the tumor microenvironment as immunopermissive. Using a mouse model of melanoma, this triple combination of biotherapy, PTT, and sustainable programmed cell death‐1 (PD‐1) blockade shows high efficiency on eliciting robust antitumor immune responses and eliminating relatively large tumors in 50% of animals within 80 days. Thus, the results shed new light on a previously unrecognized immunological facet of bacteria‐mediated therapy, and this innovative triple therapy may be a powerful cancer immunotherapy tool.     

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.     

Dual‐Targeting Heparin‐Based Nanoparticles that Re‐Assemble in Blood for Glioma Therapy through Both Anti‐Proliferation and Anti‐Angiogenesis

The efficient and specific delivery of nanoparticles (NPs) to brain tumors is crucial for successful glioma treatment. Heparin‐based polymers decorated with two peptides self‐assemble into multi‐functional NPs that specifically target glioma cells. These NPs re‐self‐assemble to a smaller size in blood, which is beneficial for in‐vivo brain drug delivery. The hydrodynamic size of one type of these NPs is 63 ± 11 nm under blood‐mimic conditions (10% fetal bovine serum), but it is 164 ± 16 nm in water. Additionally their zeta potential is more neutral in the blood‐mimic conditions. Transmission electron microscopy reveals the morphology of the spherical NPs. In vitro experiments demonstrate that the NPs exhibit a high cellular uptake and the ability to efficiently discourage proliferation, endothelial‐lined vessels, and vasculogenic mimicry. In vivo studies demonstrate that the NPs can by‐pass the normal blood–brain and blood–(brain tumor) barriers and specifically accumulate in glioma tissues; moreover, they present an excellent anti‐glioma effect in subcutaneous/intracranial glioma‐bearing mice. Their superiority is due to their appropriate size in blood and the synergic effect arising from their targeting of two different receptors. The data suggests that these NPs are ideal for anti‐glioma therapy.     

Polycationic Synergistic Antibacterial Agents with Multiple Functional Components for Efficient Anti‐Infective Therapy

Multifunctional antibacterial photodynamic therapy is a promising method to combat regular and multidrug‐resistant bacteria. In this work, eosin Y (EY)‐based antibacterial polycations (EY‐QEGED? R, R = ? CH₃ or ? C₆H₁₃) with versatile types of functional components including quaternary ammonium, photosensitizer, primary amine, and hydroxyl species are readily synthesized based on simple ring‐opening reactions. In the presence of light irradiation, such antibacterial polymers exhibit high antibacterial efficiency against both Escherichia coli and Staphylococcus aureus. In particular, EY‐QEGED? R elicits a remarkable synergistic antibacterial activity owing to the combined photodynamic and quaternary ammonium antibacterial effects. Due to its rich primary amine groups, EY‐QEGED? R also can be readily coated on different substrates, such as glass slides and nonwoven fabrics via an adhesive layer of polydopamine. The resultant surface coating of EY‐QEGED? CH₃ (s‐EY‐QEGED? CH₃) produces excellent in vitro antibacterial efficacy. The plentiful hydroxyl groups impart s‐EY‐QEGED? CH₃ with potential antifouling capability against dead bacteria. The antibacterial polymer coatings also demonstrate low cytotoxicity and good hemocompatibility. More importantly, s‐EY‐QEGED? CH₃ significantly enhances in vivo therapeutic effects on an infected rat model. The present work provides an efficient strategy for the rational design of high‐performance antibacterial materials to fight biomedical device‐associated infections.     

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.     

A Self‐Transformable pH‐Driven Membrane‐Anchoring Photosensitizer for Effective Photodynamic Therapy to Inhibit Tumor Growth and Metastasis

Poor tumor selectivity and short life span of reactive oxygen species (ROS) are two major challenges in photodynamic therapy (PDT). In this study, a self‐transformable pH‐driven membrane anchoring photosensitizer (pHMAPS) is used to realize tumor‐specific accumulation and in situ PDT on tumor cell membrane to maximize the therapeutic potency. It is found that pHMAPS was able to form α‐helix structure under acidic condition (pH 6.5 or 5.5), while remain random coil at normal pH of 7.4. This pH‐driven secondary structure switch enables the successful insertion of pHMAPS into membrane lipid bilayer, especially for cancerous cell membrane in the acidic tumor microenvironment. Under laser irradiation, cytotoxic ROS is generated in the immediate vicinity of cell membrane, resulting in superior cell killing effect in vitro and significant inhibition of tumor growth in vivo. Importantly, benefited from this membrane‐specific PDT, tumor growth‐induced hepatic, pulmonary, as well as osseous metastases of breast cancer cells are also retarded after PDT treatment. Thus, the membrane localized PDT by pHMAPS provides a simple but effective strategy to enhance the medical performance of photosensitizing agents in cancer therapy.     

Interfering with Lactate‐Fueled Respiration for Enhanced Photodynamic Tumor Therapy by a Porphyrinic MOF Nanoplatform

Lactate is a prominent energy substrate for oxidative tumor cells. Interfering with the lactate‐fueled respiration of oxidative tumor cells would be a promising therapeutic strategy for cancer treatment. In this study, α‐cyano‐4‐hydroxycinnamate (CHC) is incorporated into a porous Zr (IV)‐based porphyrinic metal‐organic framework (PZM) nanoparticle, to reduce the lactate uptake by inhibiting the expression of lactate‐proton symporter, monocarboxylate transporter 1 (MCT1) in tumor cells, thus transform lactate‐fueled aerobic respiration to anaerobic glycolysis. The alteration in energy supply can also decrease the oxygen consumption in tumor cells, which would facilitate the photodynamic therapy (PDT) in cancer treatment. Moreover, hyaluronic acid (HA) is coated on the surface of PZM nanoparticles for CD44‐targeting and hyaluronidase‐induced intracellular drug releasing. Both in vitro and in vivo studies confirmed good biocompatibility and enhanced PDT efficacy of the HA‐coated PZM nanoparticles (CHC‐PZM@HA) in tumor cells. The CHC‐PZM@HA platform will provide a new perspective in 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.     

Perfluorocarbon‐Loaded and Redox‐Activatable Photosensitizing Agent with Oxygen Supply for Enhancement of Fluorescence/Photoacoustic Imaging Guided Tumor Photodynamic Therapy

The wide clinical application of photodynamic therapy (PDT) is hampered by poor water solubility, low tumor selectivity, and nonspecific activation of photosensitizers, as well as tumor hypoxia which is common for most solid tumors. To overcome these limitations, tumor‐targeting, redox‐activatable, and oxygen self‐enriched theranostic nanoparticles are developed by synthesizing chlorin e6 (Ce6) conjugated hyaluronic acid (HA) with reducible disulfide bonds (HSC) and encapsulating perfluorohexane (PFH) within the nanoparticles (PFH@HSC). The fluorescence and phototoxicity of PFH@HSC nanoparticles are greatly inhibited by a self‐quenching effect in an aqueous environment. However, after accumulating in tumors through passive and active tumor‐targeting, PFH@HSC appear to be activated from “OFF” to “ON” in photoactivity by the redox‐responsive destruction of the vehicle's structure. In addition, PFH@HSC can load oxygen within lungs during blood circulation, and the oxygen dissolved in PFH is slowly released and diffuses over the entire tumor, finally resulting in remarkable tumor hypoxia relief and enhancement of PDT efficacy by generating more singlet oxygen. Taking advantage of the excellent imaging performance of Ce6, the tumor accumulation of PFH@HSC can be monitored by fluorescent and photoacoustic imaging after intravenous administration into tumor‐bearing mice. This PFH@HSC nanoparticle might have good potential for dual imaging‐guided PDT in hypoxic solid tumor treatment.     

Zwitterionic Polysulfamide Drug Nanogels with Microwave Augmented Tumor Accumulation and On‐Demand Drug Release for Enhanced Cancer Therapy

Zwitterionic polymers demonstrate as a class of antifouling materials with long blood circulation in living subjects. Despite extensive research on their antifouling abilities, the responsive zwitterionic polymers that can change their properties by mild outside signals are poorly explored. Herein, a sulfamide‐based zwitterionic monomer is developed and used to synthesize a series of polysulfamide‐based (poly (2‐((2‐(methacryloyloxy)ethyl) dimethylammonio)acetyl) (phenylsulfonyl) amide (PMEDAPA)) nanogels as drug carriers for effective cancer therapy. PMEDAPA nanogels are proved to exhibit prolonged blood circulation without inducing the accelerated blood clearance phenomenon. Intriguingly, PMEDAPA nanogels can sensitively respond to hyperthermia by adjusting the crosslinker degree. After modified with transferrin (Tf), the nanogels (PMEDAPA‐Tf) achieve shielded tumor targeting at normothermia, while exhibiting recovered tumor targeting at hyperthermia, leading to enhanced tumor accumulation. Meanwhile, PMEDAPA‐Tf nanogels show superior penetration ability in 3D tumor spheroids and faster drug release at hyperthermia compared with that at normothermia. In combination with mild microwave heating (≈41 °C), the drug‐loaded PMEDAPA‐Tf nanogels show a pronounced tumor inhibition effect in a humanized orthotropic liver cancer model. Therefore, the study provides a novel hyperthermia‐responsive zwitterionic nanogel that can achieve augmented tumor accumulation and on‐demand drug release assisted with clinically used microwave heating for cancer therapy.     

Targeted Tumor Hypoxia Dual‐Mode CT/MR Imaging and Enhanced Radiation Therapy Using Dendrimer‐Based Nanosensitizers

The efficacy of radiation therapy (RT) is often limited by the poor response of hypoxia inside most solid tumors. The development of a theranostic nanoplatform for precision‐imaging‐guided sensitized RT for tumor hypoxia is still challenging. Herein, the creation of hypoxia‐targeted dendrimer‐entrapped gold nanoparticles complexed with gadolinium(III) (Gd‐Au DENPs‐Nit) for dual‐mode CT/MR imaging and sensitized RT of hypoxic tumors is reported. In this work, generation 5 poly(amidoamine) dendrimers are partially conjugated with Gd(III) chelator, entrapped with Au nanoparticles, and conjugated with hypoxia‐targeting agent nitroimidazole via a polyethylene glycol linker, and ending with chelation of Gd(III) and conversion of their leftover amine termini to acetamides. The designed dendrimer‐based nanohybrids with 3.2 nm Au cores exhibit an excellent X‐ray attenuation effect, acceptable r₁ relaxivity (1.32 mM^?1 s^?1), and enhanced cellular uptake in hypoxic cancer cells, affording efficient dual‐mode CT/MR imaging of tumor hypoxia. Under X‐ray irradiation, the Gd‐Au DENPs‐Nit nanohybrids can produce reactive oxygen species, promote DNA damage, and prevent DNA repair, facilitating sensitized RT of hypoxic cancer cells in vitro and tumor hypoxia in vivo. The developed hypoxia‐targeted dendrimer‐based nanohybrids may be employed as both contrast agents and nanosensitizers for precision tumor hypoxia imaging and sensitized tumor RT.     

Long‐Circulating Drug‐Dye‐Based Micelles with Ultrahigh pH‐Sensitivity for Deep Tumor Penetration and Superior Chemo‐Photothermal Therapy

Nanocarriers for chemo‐photothermal therapy suffer from insufficient retention at the tumor site and poor penetration into tumor parenchyma. A smart drug‐dye‐based micelle is designed by making the best of the structural features of small‐molecule drugs. P‐DOX is synthesized by conjugating doxorubicin (DOX) with poly(4‐formylphenyl methacrylate‐co‐2‐(diethylamino) ethyl methacrylate)‐b‐polyoligoethyleneglycol methacrylate (P(FPMA‐co‐DEA)‐b‐POEGMA) via imine linkage. Through the π–π stacking interaction, IR780, a near‐infrared fluorescence dye as well as a photothermal agent, is integrated into the micelles (IR780‐PDMs) with the P‐DOX. The IR780‐PDMs show remarkably long blood circulation (t_1/2β = 22.6 h). As a result, a progressive tumor accumulation and retention are presented, which is significant to the sequential drug release. Moreover, when entering into a moderate acidic tumor microenvironment, IR780‐PDMs can dissociate into small‐size conjugates and IR780, which obviously increases the penetration depth of drugs, and then improves the lethality to deep‐seated tumor cells. Owing to the high delivery efficiency and superior chemo‐photothermal therapeutic efficacy of IR780‐PDMs, 97.6% tumor growth in the A549 tumor‐bearing mice is suppressed with a low dose of intravenous injection (DOX, 1.5 mg kg^?1; IR780, 0.8 mg kg^?1). This work presents a brand‐new strategy for long‐acting intensive cancer therapy.     

Nucleus‐Targeting Gold Nanoclusters for Simultaneous In Vivo Fluorescence Imaging,Gene Delivery,and NIR‐Light Activated Photodynamic Therapy

The nucleus is one of the most important cellular organelles and molecular anticancer drugs, such as cisplatin and doxorubicin, that target DNA inside the nucleus, are proving to be more effective at killing cancer cells than those targeting at cytoplasm. Nucleus‐targeting nanomaterials are very rare. It is a grand challenge to design highly efficient nucleus‐targeting multifunctional nanomaterials that are able to perform simultaneous bioimaging and therapy for the destruction of cancer cells. Here, unique nucleus‐targeting gold nanoclusters (TAT peptide–Au NCs) are designed to perform simultaneous in vitro and in vivo fluorescence imaging, gene delivery, and near‐infrared (NIR) light activated photodynamic therapy for effective cancer cell killing. Confocal laser scanning microscopy observations reveal that TAT peptide–Au NCs are distributed throughout the cytoplasm region with a significant fraction entering into the nucleus. The TAT peptide–Au NCs can also act as DNA nanocargoes to achieve very high gene transfection efficiencies (≈81%) in HeLa cells and in zebrafish. Furthermore, TAT peptide–Au NCs are also able to sensitize formation of singlet oxygen (¹O₂) without the co‐presence of organic photosensitizers for the destruction of cancer cells upon NIR light photoexcitation.