Photodynamic nano hydroxyapatite with biofilm penetration capability for dental plaque eradication and prevention of demineralization.

Dental caries represents one of the most prevalent diseases worldwide, characteristic of the growth of dental plaque and demineralization of tooth enamel. Current medications for eradication of dental plaques and prevention of demineralization suffer from several limitations to overcome, calling for novel strategies with great potency in eliminating cariogenic bacteria and dental plaque that forms, as well as in inhibiting the demineralization of enamel, into an integrated system. Considering the potency of photodynamic therapy in bacteria inactivation and the composition of enamel, we herein report that the novel photodynamic nano hydroxyapatite (nHAP), named Ce6 @QCS/nHAP, was useful for this purpose. Ce6 @QCS/nHAP, comprised of quaternary chitosan (QCS)-coated nHAP loaded with chlorin e6 (Ce6), exhibited good biocompatibility and non-compromised photodynamic activity. In vitro studies revealed that Ce6 @QCS/nHAP could effectively associate with cariogenic Streptococcus mutans (S. mutans), leading to a significant antibacterial effect through photodynamic killing and physical inactivation against the planktonic microbe. Three-dimensional fluorescence imaging suggested that Ce6 @QCS/nHAP exhibited a superior S. mutans biofilm penetration capacity to free Ce6, resulting in effective dental plaque eradiation when light irradiation was applied. The number of surviving bacteria in biofilm was at least 2.8 log units lower in the Ce6 @QCS/nHAP group compared to that in the free Ce6 group. Further, in the S. mutans biofilm-infected artificial tooth model, treatment with Ce6 @QCS/nHAP also resulted in the significant prevention of hydroxyapatite disks from demineralization, with lower percentage of fragmentation and weight loss These data suggest that our photodynamic nanosystem can effectively eradicate dental plaque while also significantly protecting artificial tooth from demineralization, opening up new possibilities in treating bacterium-associated dental caries.

Photodynamic chitosan sponges with dual instant and enduring bactericidal potency for treating skin abscesses.

The emergence of multidrug-resistant (MDR) bacteria has made wound infection treatment difficult, calling for novel strategies for effective elimination of bacteria in wounds and promoting their recovery. Herein, we report a novel chitosan antibacterial sponge combining zinc oxide particles (ZnO) and the photosensitizer chlorin e6 (Ce6), named CS-ZnO/Ce6 sponge for combating multidrug-resistant bacteria and treating skin abscesses. The fabricated CS-ZnO/Ce6 sponge had porous structure with high porosity, conducive to absorbing the wound exudate. Meanwhile, the hemostatic property of this sponge enabled it to stop the continuous bleeding of the wound. Upon 660 nm light irradiation, the CS-ZnO/Ce6 sponge exhibited an instant photodynamic bactericidal effect against several typical MDR strains, and the presence of ZnO could continuously inhibit bacterial growth. In addition, local remedy of methicillin-resistant Staphylococcus aureus (MRSA)-infected mice with CS-ZnO/Ce6 sponge with light irradiation caused a potent immediate bacterial killing effect and prolonged bacteriostasis in mice with skin abscesses, leading to the rapid recovery of the wound. The biocompatibility of the CS-ZnO/Ce6 sponge in mice was also verified by histological examination of the main organs. Collectively, the CS-ZnO/Ce6 sponge with broad-spectrum antibacterial activity and long-term bacterial inhibition potential could be useful for treating microbial infections and accelerating wound healing.

Penetration and photodynamic ablation of drug-resistant biofilm by cationic Iron oxide nanoparticles.

As we step into the post-antibiotic era, the accelerated emergence of antibiotic-resistant pathogenic bacteria poses an increasingly serious threat to public health. The formation of antibiotic-resistant biofilms further challenges currently available drugs and treatment options, calling for novel strategies for effective ablation of such biofilm with minimal concern on safety and development of resistance. Herein, we report a novel type of photodynamic nanoagent, composed of chlorin e6 (Ce6)-loaded water-soluble chitosan-coated iron oxide nanoparticles (named Ce6@WCS-IONP), for drug-resistant bacteria killing and biofilm eradication. The fabricated Ce6@WCS-IONP has negligible toxicity to mammalian cells and exhibited equivalent singlet oxygen generation capacity to free Ce6; however, its association with methicillin-resistant Staphylococcus aureus (MRSA) was greatly enhanced, as evidenced by flow cytometry analysis and transmission electron microscope. In vitro studies verified that Ce6@WCS-IONP has superior photodynamic bactericidal effect against planktonic MRSA. Furthermore, with the aid of the cationic nature and small size, Ce6@WCS-IONP could effectively penetrate into MRSA biofilm, revealed by 3D fluorescence imaging. Both biomass analysis and viable bacteria counting demonstrated that Ce6@WCS-IONP showed potent biofilm ablation efficacy, averagely 7.1 log unit lower than that in free Ce6 group upon identical light irradiation. In addition, local treatment of MRSA-infected mice with Ce6@WCS-IONP plus light irradiation resulted in significant antibacterial and wound healing effect, accompanied by good biocompatibility in vivo. Collectively, photosensitizer-loaded cationic IONP with effective biofilm penetration and photodynamic eradication potential might be a promising nano platform in fighting against antibiotic-resistant microbial pathogen and biofilm.

Light-Decomposable Polymeric Micelles with Hypoxia-Enhanced Phototherapeutic Efficacy for Combating Metastatic Breast Cancer.

Oxygen dependence and anabatic hypoxia are the major factors responsible for the poor outcome of photodynamic therapy (PDT) against cancer. Combining of PDT and hypoxia-activatable bioreductive therapy has achieved remarkably improved antitumor efficacy compared to single PDT modality. However, controllable release and activation of prodrug and safety profiles of nanocarrier are still challenging in the combined PDT/hypoxia-triggered bioreductive therapy. Herein, we developed a near infrared (NIR) light-decomposable nanomicelle, consisting of PEGylated cypate (pCy) and mPEG-polylactic acid (mPEG2k-PLA2k) for controllable delivery of hypoxia-activated bioreductive prodrug (tirapazamine, TPZ) (designated TPZ@pCy), for combating metastatic breast cancer via hypoxia-enhanced phototherapies. TPZ@pCy was prepared by facile nanoprecipitation method, with good colloidal stability, excellent photodynamic and photothermal potency, favorable light-decomposability and subsequent release and activation of TPZ under irradiation. In vitro experiments demonstrated that TPZ@pCy could be quickly internalized by breast cancer cells, leading to remarkable synergistic tumor cell-killing potential. Additionally, metastatic breast tumor-xenografted mice with systematic administration of TPZ@pCy showed notable tumor accumulation, promoting tumor ablation and lung metastasis inhibition with negligible toxicity upon NIR light illumination. Collectively, our study demonstrates that this versatile light-decomposable polymeric micelle with simultaneous delivery of photosensitizer and bioreductive agent could inhibit tumor growth as well as lung metastasis, representing a promising strategy for potent hypoxia-enhanced phototherapies for combating metastatic breast cancer.

Cyclo(RGD) peptide-decorated silver nanoparticles with anti-platelet potential for active platelet-rich thrombus targeting.

The development of integrated nanomedicine for prevention and early diagnosis of thrombosis is highly significant. Platelet plays a vital role in thrombotic disorders, offering an ideal target for thromboprophylaxis and imaging of thrombi. We herein fabricated cyclo(RGD) peptide-decorated AgNPs (designated cRGD-AgNPs) for active targeting platelet-rich thrombi. In vitro cytotoxicity and hemolysis assays demonstrated that cRGD-AgNPs have acceptable biocompatibility pattern. Both PEG-AgNPs (non-targeted version) and cRGD-AgNPs can inhibit agonist-mediated platelet aggregation, whereas the latter exhibited significant attenuation on platelet activation and adhesion onto collagen and fibrinogen matrix. Furthermore, the superior binding ability of cRGD-AgNPs with platelet-rich thrombus was demonstrated in static/dynamic condition in vitro. In vivo studies revealed that cRGD-AgNPs could actively target thrombi in a mouse model of carotid artery thrombi with favorable safety. Our results here suggest that cRGD-AgNPs with intrinsic anti-platelet potential might be promising nano theranostics for thromboprophylaxis and active thrombus targeting.

Decomposable black phosphorus nano-assembly for controlled delivery of cisplatin and inhibition of breast cancer metastasis.

Novel platforms for cisplatin delivery with a controllable manner and combinable with other treatment modality to achieve synergistic antitumor effect and inhibition metastasis for treatment of triple negative breast cancer (TNBC) are highly desirable. Herein, we report a black phosphorus (BP) nanosheets-based nano-assembly which consists of cisplatin, BP, polydopamine (PDA) and hyaluronic acid (HA), cisplatin/BP/PDA-HA (CBPH), for controlled delivery of cisplatin and inhibition tumor growth as well as lung metastasis of TNBC. For constructing CBPH, the surface of BP was dual modified by PDA and HA, resulting in enhanced stability, tumor target ability and photothermal efficiency of BP. Cisplatin was released in response both to internal and external stimuli existed in tumor microenvironment, including low pH, hydrogen peroxide and NIR light, as accompanied by decomposition of BP. In vitro experiments demonstrated CBPH-treated 4 T1 cells showed elevated intracellular content of Pt and Pt-DNA adduct, which was further improved when exposure to NIR light, leading to potent antitumor effect in a synergistic pattern. Anti-metastasis studies in 2D monolayers and 3D organoids revealed that CBPH plus NIR light treatment exhibited significantly decreased migration, invasion and regrowth ability of 4 T1 cells. Furthermore, TNBC-bearing mice with systemic administrate of CBPH showed enhanced tumor accumulation of cisplatin and light-triggered inhibition of tumor growth at primary site and lung metastasis, with alleviated toxicity. But CBPH is yet to be optimized for realizing smart cisplatin delivery in response to acidic and redox stimuli in vivo. Collectively, our study demonstrates that this novel BP-based nano-assembly with controllable tumor delivery of cisplatin and metastasis inhibition of breast cancer expand the use of BP in biomedicine field and hold great promise for further development.