Single Near-infrared Irradiation Research Articles

Integrating L-cysteine coated polydopamine nanoparticles and deep eutectic solvents into chitosan matrix for multifunctional food packaging application

To reduce the deterioration of fruits and vegetables caused by food-borne microorganisms, this study proposed a bio-sustainable PCD-CS photothermal bactericidal nanocomposite film. This film integrated L-Cysteine (L-Cys) coated polydopamine nanoparticles (PDA@L-Cys NPs) and deep eutectic solvents (DES) into the chitosan (CS) matrix. The DES effectively improved the mechanical property of composite film, water vapor barrier property (WVP), transparency, and biodegradability. The inclusion of PDA@L-Cys NPs significantly increased the oxidation resistance, UV-shielding, and photothermal conversion capabilities. The oxidation resistance of composite film improved 3–7 times compared to the bare CS film. Under near-infrared irradiation (NIR) for just 10 min, the temperature of the film can rise to 55.8 °C, achieving a photothermal antibacterial rate reached 99.9% against Escherichia coli (E. coli, ATCC 8739) and Staphylococcus aureus (S. aureus, ATCC 6538). Under single short-time NIR trigger, the PCD-CS nanocomposite film effectively maintained good color, pH value, soluble solid content (TSS), and appearance of cherry tomato, and delayed the decrease of weight. The successful implementation of this work provides new insights and approaches for creating and advancing sustainable antibacterial food packaging.

Novel biodegradable two-dimensional vanadene augmented photoelectro-fenton process for cancer catalytic therapy

Fenton reaction-based chemodynamic therapy is hardly a self-sufficient cancer treatment, due to its stringent reaction conditions, limited substrate concentration, and negative feedback from the tumor microenvironment. Herein, we synthesized a novel two-dimensional (2D) vanadium-based nanosheets (Vanadene, V NSs) with polyvalent surfaces (VIV/VV), a very narrow band gap of 0.8 eV, and high biodegradability by a liquid-phase exfoliation strategy. The polyvalent surface endowed its multiple capabilities to modulate TME through GSH consumption and O2 production via VV and to catalyze a Fenton-like reaction to produce ·OH under a mild condition via VIV. In addition, efficient energy conversions including near-infrared (NIR)-thermal conversion (photothermal therapy, PTT) and NIR-electron conversion (photodynamic therapy, PDT) were ensured by the narrow band gap, in which NIR-thermal conversion enhanced the Fenton-like reaction activity through accelerating ionization while NIR-electron conversion catalyzed the conversion of O2 to ·O2− for further breaking redox homeostasis. Moreover, V NSs-based nanocatalyst can be slowly degraded into non-toxic species, enabling it to be innocuously eliminated from the body after completing tumor eradication by single drug injection and single NIR irradiation. Therefore, this study provides new insights into a universal nanoplatform for NIR-enhanced combination cancer therapy, highlighting the utility of 2D V NSs in the field of biomedicine.

TB@PLGA Nanoparticles for Photodynamic/Photothermal Combined Cancer Therapy with Single Near-Infrared Irradiation.

BackgroundPhototherapy has significant potential as an effective treatment for cancer. However, the application of a multifunctional nanoplatform for photodynamic therapy (PDT) and photothermal therapy (PTT) at a single excitation wavelength remains a challenge.Materials and MethodsThe double emulsion solvent evaporation method was used to prepare toluidine blue@poly lactic-co-glycolic acid (TB@PLGA) nanoparticles (NPs). The biocompatibility of TB@PLGA NPs was evaluated, and a 660 nm luminescence was used as the light source. The photothermal effect, photothermal stability, and singlet oxygen yield of NPs in an aqueous solution verified the feasibility of NPs as a PTT/PDT synergistic therapy drug.ResultsTB@PLGA NPs were successfully prepared and characterized. In vitro experiments demonstrated that TB@PLGA NPs can cause massive necrosis of tumor cells and induce apoptosis through a photodynamic mechanism under 660 nm laser irradiation. The TB@PLGA NPs also achieved optimal tumor inhibition effect in vivo.ConclusionThe TB@PLGA NPs prepared in this study were applied as a dual-mode phototherapeutic agent under single laser irradiation. Both in vitro and in vivo experiments demonstrated the good potential of PTT/PDT for tumor inhibitors.

Near-Infrared Regulated Nanozymatic/Photothermal/Photodynamic Triple-Therapy for Combating Multidrug-Resistant Bacterial Infections via Oxygen-Vacancy Molybdenum Trioxide Nanodots.

Bacterial infections have become a major danger to public health because of the appearance of the antibiotic resistance. The synergistic combination of multiple therapies should be more effective compared with the respective one alone, but has been rarely demonstrated in combating bacterial infections till now. Herein, oxygen-vacancy molybdenum trioxide nanodots (MoO3-x NDs) are proposed as an efficient and safe bacteriostatic. The MoO3-x NDs alone possess triple-therapy synergistic efficiency based on the single near-infrared irradiation (808 nm) regulated combination of photodynamic, photothermal, and peroxidase-like enzymatic activities. Therein, photodynamic and photothermal therapies can be both achieved under the excitation of a single wavelength light source (808 nm). Both the photodynamic and nanozyme activity can result in the generation of reactive oxygen species (ROS) to reach the broad-spectrum sterilization. Interestingly, the photothermal effect can regulate the MoO3-x NDs to their optimum enzymatic temperature (50 °C) to give sufficient ROS generation in low concentration of H2 O2 (100 µm). The MoO3-x NDs show excellent antibacterial efficiency against drug-resistance extended spectrum β-lactamases producing Escherichia coli and methicillin-resistant Staphylococcus aureus (MRSA). Animal experiments further indicate that the MoO3-x NDs can effectively treat wounds infected with MRSA in living systems.

NIR-Responsive Polypeptide Nanocomposite Generates NO Gas, Mild Photothermia, and Chemotherapy to Reverse Multidrug-Resistant Cancer.

Multidrug resistance (MDR) of cancers that results from overexpression of a P-glycoprotein (P-gp) transporter mainly causes chemotherapy (CT) failure and hinders clinical transitions of current polypeptide nanomedicines. Herein, a novel polypeptide nanocomposite PNOC-PDA that integrates heat-sensitive NO gas delivery and photothermal conversion attributes can overcome MDR and maximize CT; meanwhile the optimized CT and intracellular high-concentration NO gas can assist a mild photothermal therapy (PTT) to eradicate cancer cells. The triple therapies produced a superior and synergistic effect on MDR-reversal and killing MCF-7/ADR in vitro, and the P-gp expression level was downregulated to 46%, as confirmed by means of MTT, Western blot, flow cytometry, and confocal laser scanning microscopy. Significantly, by using one intravenous injection of PNOC-PDA/DOX and a single near-infrared irradiation, the triple therapies of mild PTT, NO gas therapy, and CT achieved complete MCF-7/ADR tumor ablation without skin damage, scarring, and tumor recurrence within 30 days. This work provides a versatile method for the fabrication of NIR-responsive polypeptide nanocomposite with intrinsic photothermal conversion and NO-releasing attributes, opening up a new avenue for reversing MDR in tumors.

Cancer Therapy: Mitochondria‐Targeted Artificial “Nano‐RBCs” for Amplified Synergistic Cancer Phototherapy by a Single NIR Irradiation (Adv. Sci. 8/2018)

In article number 1800049, Dong Wang, Yu Chen, and co-workers report amplification of photo-therapeutic efficacy by constructing a near infrared (NIR)-responsive multifunctional nanoplatform, i.e., Nano-RBCs (red blood cells), for synergistic cancer phototherapy using a single NIR irradiation (808 nm laser). The Nano-RBCs concurrently achieve mitochondria-targeting phototherapy, synergistic photothermal therapy (PTT)/photodynamic therapy (PDT), self-sufficient oxygen-augmented PDT, and multiple-imaging guidance/monitoring.

Theranostic Mn-Porphyrin Metal-Organic Frameworks for Magnetic Resonance Imaging-Guided Nitric Oxide and Photothermal Synergistic Therapy.

Chemotherapy remains restricted by its toxic adverse effects and resistance to drugs. The treatment of nitric oxide (NO) combined with imaging-guided physical therapy is a promising alternative for clinical applications. Herein, we report nanoscale metal-organic framework (NMOF) systems to integrate magnetic resonance (MR) imaging, spatiotemporally controllable NO delivery, and photothermal therapy (PTT) as a new means of cancer theranostics. As a proof of concept, the NMOFs are prepared with biocompatible Zr4+ ions and Mn-porphyrin as a bridging ligand. By inserting paramagnetic Mn ions into porphyrin rings, Mn-porphyrin renders the NMOFs strong T1-weighted MR contrast capacity and high photothermal conversion for efficient PTT. S-Nitrosothiol (SNO) is conjugated to the surfaces of the NMOFs for heat-sensitive NO generation. Moreover, single near-infrared (NIR) light triggers the controllable NO release and PTT simultaneously for their efficient synergistic therapy with one-step operation. Upon intravenous injection, NMOF-SNO shows effective tumor accumulation as exposed by the MR images of the tumor-bearing mice. When exposed to the NIR laser, the tumors of mice injected with NMOF-SNO are completely inhibited, verifying the efficiency of NMOF-SNO. For the first time, Mn-porphyrin NMOFs are developed to be an effective theranostic system for MR imaging-guided controllable NO release and photothermal synergetic therapy under single NIR irradiation.

Mitochondria-Targeted Artificial "Nano-RBCs" for Amplified Synergistic Cancer Phototherapy by a Single NIR Irradiation.

Phototherapy has emerged as a novel therapeutic modality for cancer treatment, but its low therapeutic efficacy severely hinders further extensive clinical translation and application. This study reports amplifying the phototherapeutic efficacy by constructing a near‐infrared (NIR)‐responsive multifunctional nanoplatform for synergistic cancer phototherapy by a single NIR irradiation, which can concurrently achieve mitochondria‐targeting phototherapy, synergistic photothermal therapy (PTT)/photodynamic therapy (PDT), self‐sufficient oxygen‐augmented PDT, and multiple‐imaging guidance/monitoring. Perfluorooctyl bromide based nanoliposomes are constructed for oxygen delivery into tumors, performing the functions of red blood cells (RBCs) for oxygen delivery (“Nano‐RBC” nanosystem), which can alleviate the tumor hypoxia and enhance the PDT efficacy. The mitochondria‐targeting performance for enhanced and synergistic PDT/PTT is demonstrated as assisted by nanoliposomes. In particular, these “Nano‐RBCs” can also act as the contrast agents for concurrent computed tomography, photoacoustic, and fluorescence multiple imaging, providing the potential imaging capability for phototherapeutic guidance and monitoring. This provides a novel strategy to achieve high therapeutic efficacy of phototherapy by the rational design of multifunctional nanoplatforms with the unique performances of mitochondria targeting, synergistic PDT/PTT by a single NIR irradiation (808 nm), self‐sufficient oxygen‐augmented PDT, and multiple‐imaging guidance/monitoring.

A perylene diimide zwitterionic polymer for photoacoustic imaging guided photothermal/photodynamic synergistic therapy with single near-infrared irradiation.

Phototherapy has great promise for precise cancer diagnosis and effective therapy, but the development of one multifunctional nanoplatform for synergistic photodynamic therapy (PDT) and photothermal therapy (PTT) at a single excitation wavelength remains a challenge. In this work, a perylene diimide zwitterionic polymer PDS-PDI was synthesized via atom transfer radical polymerization (ATRP). This polymer was designed for photoacoustic imaging (PAI) guided synergistic PDT and PTT with single 660 nm near-infrared (NIR) light irradiation. The prepared PDS-PDI polymer presents high photothermal conversion efficiency (η≈ 40%) and efficient singlet oxygen quantum yield (ΦΔ≈ 16.7%) under 660 nm laser irradiation. Polymer PDS-PDI also acts as a contrast agent for PAI, offering real-time monitoring in tumor sites. Additionally, in vitro and in vivo assays indicate that polymer PDS-PDI has good biocompatibility and effective tumor destruction ability under 660 nm laser irradiation. In brief, polymer PDS-PDI prepared in this study could be applied as a dual-mode phototherapeutic agent under single laser irradiation.