Synergistic Triple-Modal Nanoplatform Integrating Fluorescence Imaging and Chemo-Photothermal/Photodynamic Therapy for Targeted Cancer Treatment.

Multifunctional nanohybrids integrating diagnostic imaging with photodynamic or photothermal therapy in a single agent feature the next generation of on-demand nanomedicine to meet the challenges in cancer therapy. In the present study, bovine serum albumin (BSA) protein through one pot biomimetic mineralization at its metal binding site synthesized and stabilized manganese-doped copper selenide nanoparticles (Mn:CuSe) with excellent biocompatibility, near-infrared absorption, water solubility, and rich functional groups for further bioconjugation. Mn doping not only imparted the magnetic resonance imaging (MRI) function to the Mn:CuSe@BSA but also enhanced its heat generation ability. By taking advantage of BSA's extraordinary ligand binding capacity, folic acid (FA) and chlorin e6 (Ce6) were then conjugated onto the BSA corona to construct the Mn:CuSe@BSA-FA-Ce6 nanohybrid for specific targeting of overexpressed folate receptor cancer cells. The obtained theranostic agent exhibited dual MRI signal enhancement and synergistic photothermal/photodynamic therapy (PTT/PDT) effect, which was demonstrated in vitro on HeLa cells. As a consequence, dual modal therapy with 1 min PDT laser irradiation doubled cell killing efficiency compared to the single PDT treatment. Having better efficacy regarding biocompatibility and synergistic light-activation therapy, the Mn:CuSe@BSA-FA-Ce6 nanohybrid holds the promise for image-guided cancer therapy.

Tumor-targeting nanogel that can function independently for both photodynamic and photothermal therapy and its synergy from the procedure of PDT followed by PTT

Achieving an integrated system for combinational therapy of cancer with enhanced efficacy is always a challenge. A multifunctional system (CCeT nanoparticles (NPs)) for a synergistic photodynamic and photothermal cancer therapy was successfully developed. This system is composed of Cu2- xS nanoclusters functionalized with chlorin e6 (Ce6)-conjugated branched polyethylenimine (PEI-Ce6) and mitochondria-targeting 3-(carboxypropyl)triphenylphosphonium bromide (TPP-COOH). The colocalization of the resulted CCeT NPs inside the mitochondria of cancer cells was proven. The CCeT NPs exhibited significant photodynamic therapy (PDT) efficacy due to efficient singlet oxygen (1O2) generation triggered by a 630 nm laser. This system also showed excellent photothermal conversion capability upon the irradiation of 808 nm laser for photothermal therapy (PTT). In particular, the platform achieved nearly 100% inhibitory rate of the tumor growth in vivo through combinational PDT and PTT. Thus, the CCeT NPs could efficiently inhibit the tumor growth in vitro and in vivo by combinational PDT and PTT, offering synergistic therapeutic efficiency as compared to PTT or PDT alone.

Albumin as a functional carrier enhances solubilization, photodynamic and photothermal antibacterial therapy of curcumin.

Graphene oxide (GO) is one of the most studied nanomaterials in many fields, including the biomedical field. Most of the nanomaterials developed for drug delivery and phototherapies are based on noncovalent approaches that lead to an unspecific release of physisorbed molecules in complex biological environments. Therefore, preparing covalently functionalized GO using straightforward and versatile methods is highly valuable. Phototherapies, including photothermal therapy (PTT) and photodynamic therapy (PDT), have shown great potential as effective therapeutic approaches against cancer. To overcome the limits of a single method, the combination of PTT and PDT can lead to a combined effect with a higher therapeutic efficiency. In this work, we prepare a folic acid (FA) and chlorin e6 (Ce6) double-functionalized GO for combined targeted PTT/PDT. This conjugate can penetrate rapidly into cancer cells and macrophages. A combined effect of PTT and PDT is observed, leading to a higher killing efficiency toward different types of cells involved in cancer and other diseases. Our work provides a simple protocol to prepare multifunctional platforms for the treatment of various diseases.

Graphene quantum dots (GQDs) hold great promise for photodynamic and photothermal cancer therapies. Their unique properties, such as exceptional photoluminescence, photothermal conversion efficiency, and surface functionalization capabilities, make them attractive candidates for targeted cancer treatment. GQDs have a high photothermal conversion efficiency, meaning they can efficiently convert light energy into heat, leading to localized hyperthermia in tumors. By targeting the tumor site with laser irradiation, GQD-based nanosystems can induce selective cancer cell destruction while sparing healthy tissues. In photodynamic therapy, light-sensitive compounds known as photosensitizers are activated by light of specific wavelengths, generating reactive oxygen species that induce cancer cell death. GQD-based nanosystems can act as excellent photosensitizers due to their ability to absorb light across a broad spectrum; their nanoscale size allows for deeper tissue penetration, enhancing the therapeutic effect. The combination of photothermal and photodynamic therapies using GQDs holds immense potential in cancer treatment. By integrating GQDs into this combination therapy approach, researchers aim to achieve enhanced therapeutic efficacy through synergistic effects. However, biodistribution and biodegradation of GQDs within the body present a significant hurdle to overcome, as ensuring their effective delivery to the tumor site and stability during treatment is crucial for therapeutic efficacy. In addition, achieving precise targeting specificity of GQDs to cancer cells is a challenging task that requires further exploration. Moreover, improving the photothermal conversion efficiency of GQDs, controlling reactive oxygen species generation for photodynamic therapy, and evaluating their long-term biocompatibility are all areas that demand attention. Scalability and cost-effectiveness of GQD synthesis methods, as well as obtaining regulatory approval for clinical applications, are also hurdles that need to be addressed. Further exploration of GQDs in photothermal and photodynamic cancer therapies holds promise for advancements in targeted drug delivery, personalized medicine approaches, and the development of innovative combination therapies. The purpose of this review is to critically examine the current trends and advancements in the application of GQDs in photothermal and photodynamic cancer therapies, highlighting their potential benefits, advantages, and future perspectives as well as addressing the crucial challenges that need to be overcome for their practical application in targeted cancer therapy.

Light-activated therapies are ideal for treating cancer because they are non-invasive and highly specific to the area of light application. Photothermal therapy (PTT) and photodynamic therapy (PDT) are two types of light-activated therapies that show great promise for treating solid tumors. In PTT, nanoparticles embedded within tumors emit heat in response to laser light that induces cancer cell death. In PDT, photosensitizers introduced to the diseased tissue transfer the absorbed light energy to nearby ground state molecular oxygen to produce singlet oxygen, which is a potent reactive oxygen species (ROS) that is toxic to cancer cells. Although PTT and PDT have been extensively evaluated as independent therapeutic strategies, they each face limitations that hinder their overall success. To overcome these limitations, we evaluated a dual PTT/PDT strategy for treatment of triple negative breast cancer (TNBC) cells mediated by a powerful combination of silica core/gold shell nanoshells (NSs) and palladium 10,10-dimethyl-5,15-bis(pentafluorophenyl)biladiene-based (Pd[DMBil1]-PEG750) photosensitizers (PSs), which enable PTT and PDT, respectively. We found that dual therapy works synergistically to induce more cell death than either therapy alone. Further, we determined that low doses of light can be applied in this approach to primarily induce apoptotic cell death, which is vastly preferred over necrotic cell death. Together, our results show that dual PTT/PDT using silica core/gold shell NSs and Pd[DMBil1]-PEG750 PSs is a comprehensive therapeutic strategy to non-invasively induce apoptotic cancer cell death.

Photodynamic therapy (PDT) is a clinically approved and minimally invasive form of cancer treatment. However, due to hypoxia at the tumor site and phototoxicity to normal tissues, monotherapies using photosensitizers remain suboptimal. This study aimed to develop a highly selective controlled catalase-enhanced synergistic photodynamic and photothermal cancer therapy based on gold nanostars.Methods: Gold nanostars (GNS) with high thermal conversion efficiency were used as the core for photothermal therapy (PTT) and the shell consisted of the photosensitizer Ce6-loaded mesoporous silicon. The shell was modified with catalase (E), which catalyzes the conversion of hydrogen peroxide to oxygen at the tumor site, alleviating hypoxia and increasing the effect of the photodynamic treatment. Finally, a phospholipid derivative with c(RGDyK) was used as the targeting moiety and the nanoparticle-encapsulating material.Results: The nanoprobe exhibited good dispersion, high stability, and high photothermal conversion efficiency (~28%) for PTT as well as a photodynamic "on-off" effect on Ce6 encapsulated in mesoporous channels. The "release" of Ce6 was only triggered under photothermal stimulation in vivo. Due to its targeting ability, 72 h after injection of the probe, the tumor site in mice showed an observable CT response. The combined treatment using photothermal therapy (PTT) and catalase-enhanced photo-controlled PDT exerted a superior effect to PTT or PDT monotherapies.Conclusion: Our findings demonstrate that the use of this intelligent nanoprobe for CT-targeted image-guided treatment of tumors with integrated photothermal therapy (PTT) and catalase-enhanced controlled photodynamic therapy (PDT) may provide a novel approach for cancer theranostics.

Photosensitizer-loaded gold nanorods for near infrared photodynamic and photothermal cancer therapy

Breast cancer is a neoplastic disease with a high mortality rate among women. Recently, photodynamic therapy (PDT) and photothermal therapy (PTT) attracted considerable attention because of their minimal invasiveness. The PTT approach works based on hyperthermia generation, and PDT approach employs laser irradiation to activate a reagent named photosensitizer. Therefore, in the current paper, a dual-functioned nanocomposite (NC) was designed for the treatment of breast cancer model in Balb/c mice with the combination of photodynamic and photothermal approaches. Transmission electron microscopy, UV–visible spectroscopy, FTIR, and XRD were employed to validate the nanostructure and silica coating and curcumin (CUR) immobilization on the Fe3O4 nanoparticles. The effect of Fe3O4/SiO2-CUR combined with PDT and PTT was assessed in vivo on the breast tumor mice model, and immunohistochemistry (IHC) was employed to evaluate the expression of apoptotic Bax and Caspase3 proteins. The TEM images, UV–visible absorption, and FTIR spectra demonstrated the successful immobilization of curcumin molecules on the surface of Fe3O4/SiO2. Also, MTT assay confirmed the nontoxic nature of Fe3O4/SiO2 nanoparticles in vitro. In the breast tumor mice model, we have assessed six treatment groups, including control, CUR + PDT, Blue + NIR (near-infrared) lasers, NC, NC + PTT, and NC + PDT + PTT. The tumor volume in the NC + PDT + PTT group showed a significant reduction compared to other groups (p < 0.05). More interestingly, the tumor volume of NC + PDT + PTT group showed a 27% decrease compared to its initial amount. It should be noted that no detectable weight loss or adverse effects on the vital organs was observed due to the treatments. Additionally, the IHC data represented that the expression of proapoptotic Bax and Caspase3 proteins were significantly higher in the NC + PDT + PTT group compared to the control group, indicative of apoptosis. To conclude, our data supported the fact that the NC + PDT + PTT strategy might hold a promising substitute for chemotherapy for the treatment of triple-negative breast cancers.

The treatment of cancer has become a profoundly intricate procedure. Traditional treatment methods, including chemotherapy, surgery and radiotherapy, have been utilized, while notable progress has been achieved in recent years. Among targeted therapies for cancer, folic acid (FA) conjugated metal-based nanoparticles (NP) have emerged as an innovative strategy, namely for photodynamic therapy (PDT) and photothermal therapy (PTT). These NP exploit the strong attraction between FA and folate receptors, which are excessively produced in several cancer cells, in order to enable precise administration and improved effectiveness of treatment. During PDT, metal-based NP functionalized with FA are used as photosensitizers which are activated by light, and produce reactive oxygen species that cause cancer cells to undergo apoptosis. Within the framework of PTT, these NP effectively transform light energy into concentrated heat, specifically targeting and destroying tumor cells. This review examines the fundamental mechanisms by which these NP improve the effectiveness of PDT and PTT while simultaneously presenting important findings that demonstrate the effectiveness of FA-functionalized MNP in laboratory and animal models. In addition, the paper also discusses the problems and potential directions for their clinical translation.

Rational design for the microplasma synthesis from vitamin B9 to N-doped carbon quantum dots towards selected applications

Insights into the newly synthesized N-doped carbon dots for Q235 steel corrosion retardation in acidizing media: A detailed multidimensional study

A theranostic nanocomposite with integrated black phosphorus nanosheet, Fe3O4@MnO2-doped upconversion nanoparticles and chlorin for simultaneous multimodal imaging, highly efficient photodynamic and photothermal therapy

Herein, we have developed a composite antibacterial hydrogel with photodynamic therapy (PDT) and photothermal therapy (PTT) antibacterial capabilities, triggered by white light and NIR light irradiation. A water-insoluble conjugated polymer (PDPP) with photothermal ability was prepared into nanoparticles by the nanoprecipitation method, and the cell-penetrating peptide TAT was grafted on the surface of the nanoparticles. Based on our previous work that developed a hybrid hydrogel with an enhanced PDT effect from polyisocyanide (PIC) hydrogel and cationic conjugated polythiophene (PMNT), PDPP nanoparticles (CPNs-TAT) with photothermal ability are introduced to realize the synergistic antibacterial effect of PDT and PTT. Using the PIC hydrogel to combine PIC and CPNs-TAT has the following advantages. First, the PIC hydrogel can regulate the aggregation state of PMNT, making it better dispersed and improving its capacity of reactive oxygen species (ROS) production. Second, CPNs-TAT can be uniformly dispersed in the PIC hybrid, thereby avoiding the toxicity caused by too high local concentration, achieving a uniform increase in system temperature, and enhancing the therapeutic effect of PTT. Third, the PIC hybrid has the synergistic treatment effect of PDT and PTT. The PIC hybrid intelligently regulates its antibacterial ability through white light and NIR light, which can be used in the white light and NIR light areas. When irradiated with white light and NIR light sequentially, synergistic PDT and PTT exhibit stronger antibacterial ability than PDT or PTT alone. The combination of two antibacterial methods realizes the dual-control antibacterial hydrogel of PDT and PTT and provides an antibacterial mode based on PIC hybrids. Therefore, the PIC hybrids are promising as an antibacterial excipient for clinical wounds.