Andrea del Valle scite author profile

et al. 2017

Nanoscale

Clinical applications of current photodynamic therapy (PDT) agents are often restricted to be activated only by UV and visible light, which have very poor tissue penetration depths. In this study, a new near infrared (NIR)-absorbing nanoagent based on graphene oxide decorated with iron hydroxide/oxide (GO-FeOH) was developed for light-activated nanomaterial-mediated PDT. This nanocomposite, GO-FeOH was prepared via the one-step electrooxidation of iron nails in an aqueous GO solution. The as-prepared GO-FeOH showed a much higher reactive oxygen species (ROS) activity under NIR light irradiation than GO. Through a variety of spectroscopic analyses, the mechanism involved in the enhancement of ROS activity of GO by FeOH was systematically investigated. We observed that NIR light irradiation promotes electron transfer from GO to the Fe(iii) of FeOH and accelerates their reaction with O, forming superoxide anion radicals, which then undergo a disproportionation reaction to produce HO. HO then reacts with Fe(ii) in FeOH to mediate Fenton reactions, producing amplified hydroxyl radicals. Using in vitro studies, we demonstrated that GO-FeOH can be used as a NIR activatable PDT nanoagent, providing efficient cancer therapy.

A New Photosensitized Oxidation-Responsive Nanoplatform for Controlled Drug Release and Photodynamic Cancer Therapy

Yeh

ACS Appl. Mater. Interfaces

Syu

et al. 2018

Abnormal biochemical alteration such as unbalanced reactive oxygen species (ROS) levels has been considered as a potential disease-specific trigger to deliver therapeutics to target sites. However, in view of their minute variations in concentration, short lifetimes, and limited ranges of action, in situ generation of ROS with specific manipulations should be more effective for ROS-responsive drug delivery. Here we present a new delivery nanoplatform for photodynamic therapy (PDT) with on-demand drug release regulated by light irradiation. Rose bengal (RB) molecules, which exhibit a high yield of ROS generation, were encapsulated in a mixture of chitosan (CTS), poly(vinyl alcohol) (PVA), and branched polyethylenimine ( bPEI) with hydrophobic iron oxide nanoparticles through an oil-in-water emulsion method. The as-prepared magnetic nanoclusters (MNCs) with a tripolymer coating displayed high water dispersibility, efficient cellular uptake, and the cationic groups of CTS and bPEI were effective for RB loading through electrostatic interaction. The encapsulation efficiency of RB in MNCs could be further improved by increasing the amount of short bPEI chains. During the photodynamic process, controlled release of the host molecules (i.e., RB) or guest molecules (i.e., paclitaxel) from the bPEI-based nanoplatform was achieved simultaneously through a photooxidation action sensitized by RB. This approach promises specific payload release and highly effective PDT or PDT combined therapy in various cancer cell lines including breast (MCF-7 and multidrug resistant MCF-7 subline), SKOV-3 ovarian, and Tramp-C1 prostate. In in vivo xenograft studies, the nanoengineered light-switchable carrier also greatly augments its PDT efficacy against multidrug resistant MCF-7/MDR tumor as compared with free drugs. All the above findings suggest that the substantial effects of enhanced drug distribution for efficient cancer therapy was achieved with this smart nanocarrier capable of on demand drug release and delivery, thus exerting its therapeutic activity to a greater extent.

Near Infrared‐Activatable Platinum‐Decorated Gold Nanostars for Synergistic Photothermal/Ferroptotic Therapy in Combating Cancer Drug Resistance

Adv Healthcare Materials

Yeh

Huang

2020

Ferroptotic cell death results from glutathione peroxidase 4 (GPX4) inactivation and/or glutathione (GSH) depletion. Elevated GSH levels are often found in multidrug‐resistant (MDR) tumor cells, reducing their sensitivity to chemotherapeutic drugs and the efficacy of treatment. MDR cells also acquire a dependency on GPX4, reducing their oxidative stress and promoting their survival. Therefore, the depletion of GSH and inactivation of GPX4 has the potential to be a superior treatment strategy for MDR tumors. Platinum‐decorated gold nanostars (Pt‐AuNS) are presented as a novel metal nanoprodrug for ferroptotic therapy against MDR tumors. Under dark conditions, the synthesized Pt‐AuNS exhibit negligible levels of toxicity. Upon exposure of the Pt‐AuNS to near‐infrared (NIR) light, active metallic (Pt and Au) species are released, subsequently inducing cytotoxicity. The mechanism of action is attributed to GSH depletion and GPX4 inactivation, accumulating lipid hydroperoxides, which in turn leads to ferroptosis. In in vivo xenograft, the MDR cancer model confirmed the NIR light‐activation of Pt‐AuNS prodrugs, resulting in efficient ferroptotic therapeutic action against MDR tumors without long‐term side effects. The findings lay the groundwork for using Pt‐AuNS prodrugs responsive to NIR light as ferroptosis‐inducing agents in chemo‐resistant cancer cells and demonstrate their potential for use in future clinical applications.

Development of Photo-Activated ROS-Responsive Nanoplatform as a Dual-Functional Drug Carrier in Combinational Chemo-Photodynamic Therapy

et al. 2019

Dual functional drug carrier has been a modern strategy in cancer therapy because it is a platform to elicit additive and synergistic effects through combination therapy. Photo-activated external stimuli such as reactive oxygen species (ROS) also ensure adequate drug delivery in a precise temporal and spatial manner. However, current ROS-responsive drug delivery systems usually require tedious synthetic procedures. A facile one-pot approach has been reported herein, to obtain self-assembled polymeric nanocarriers (NCs) for simultaneous paclitaxel (PTX)- and Rose Bengal (RB)-loading to achieve combined chemo-photodynamic therapy and controlled drug release in responsive to a light-induced ROS stimulus. To encapsulate these hydrophobic and hydrophilic drugs, chitosan (CTS), branched polyethylenimine (bPEI) and polyvinyl alcohol (PVA) were selected and fabricated into nanoblended matrices through an oil-in-water emulsion method. The amphiphilic properties of CTS permit simultaneous entrapment of PTX and RB, while the encapsulation efficiency of RB was further improved by increasing the amount of short-chain bPEI. During the one-step assembly process, bovine serum albumin (BSA) was also added to condense the cationic tripolymer mixtures into more stable nanocarriers (BNCs). Hyaluronic acid (HA) was subsequently grafted onto the surface of BNCs through electrostatic interaction, leading to the formation of HA-BSA/CTS/PVA/bPEI-blended nanocarriers (HBNCs) to achieve an efficient prostate-cancer-cell uptake. Importantly, in response to external light irradiation, HBNCs become destabilized owing to the RB-mediated photodynamic action. It allows an on-demand dual-payload release to evoke a simultaneous photodynamic and chemo treatment for cancer cell eradication. Thus, HBNCs present a new promising approach that exhibits a specific vulnerability to RB-induced photosensitization. The consequent dual-cargo release is also expected to successfully combat cancer through a synergistic anti-tumor effect.

NIR-cleavable drug adducts of gold nanostars for overcoming multidrug-resistant tumors

Sun

et al. 2020

Biomater. Sci.