H2O2-Activatable Antioxidant Polymeric Prodrug Nanoparticles for the Prevention of Renal Ischemia/Reperfusion Injury.

Renal ischemia-reperfusion (IR) injury is an inevitable complication in various clinical settings including kidney transplantation and major vascular surgeries. Renal IR injury is a major risk factor for acute kidney injury, which still remains a major clinical challenge without effective therapy. The main cause of renal IR injury is the massive production of reactive oxygen species (ROS) including hydrogen peroxide (H2O2) that initiate inflammatory signaling pathways, leading to renal cell death. In this study, we developed fucoidan-coated polymeric prodrug (Fu-PVU73) nanoparticles as renal IR-targeting nanotherapeutics that can rapidly eliminate H2O2 and exert anti-inflammatory and antiapoptotic effects. Fu-PVU73 nanoparticles were composed of H2O2-activatable antioxidant and anti-inflammatory polymeric prodrug (PVU73) that incorporated H2O2-responsive peroxalate linkages, ursodeoxycholic acid (UDCA), and vanillyl alcohol (VA) in its backbone. Fu-PVU73 nanoparticles rapidly scavenged H2O2 and released UDCA and VA during H2O2-triggered degradation. In the study of renal IR injury mouse models, Fu-PVU73 nanoparticles preferentially accumulated in the IR injury-induced kidney and markedly protected the kidney from IR injury by suppressing the generation of ROS and the expression of proinflammatory cytokines. We anticipate that Fu-PVU73 nanoparticles have tremendous therapeutic potential for not only renal IR injury but also various ROS-associated inflammatory diseases.

The anticancer effect of (1S,2S,3E,7E,11E)-3,7,11, 15-cembratetraen-17,2-olide(LS-1) through the activation of TGF-ß signaling in SNU-C5/5-FU, fluorouracil-resistant human colon cancer cells.

The anticancer effect of (1S,2S,3E,7E,11E)-3,7,11,15-cembratetraen-17,2-olide (LS-1) from Lobophytum sp. has been already reported in HT-29 human colorectal cancer cells. In this study, we examined the effect of LS-1 on the apoptosis induction of SNU-C5/5-FU, fluorouracil-resistant human colon cancer cells. Furthermore, we investigated whether the apoptosis-induction effect of LS-1 could arise from the activation of the TGF-ß pathway. In SNU-C5/5-FU treated with LS-1 of 7.1 µM (IC50), we could observe the various apoptotic characteristics, such as the increase of apoptotic bodies, the increase of the sub-G1 hypodiploid cell population, the decrease of the Bcl-2 level, the increase of procaspase-9 cleavage, the increase of procaspase-3 cleavage and the increase of poly(ADP-ribose) polymerase cleavage. Interestingly, the apoptosis-induction effect of LS-1 was also accompanied by the increase of Smad-3 phosphorylation and the downregulation of c-Myc in SNU-C5/5-FU. LS-1 also increased the nuclear localization of phospho-Smad-3 and Smad-4. We examined whether LS-1 could downregulate the expression of carcinoembryonic antigen (CEA), a direct inhibitor of TGF-ß signaling. LS-1 decreased the CEA level, as well as the direct interaction between CEA and TGF-ßR1 in the apoptosis-induction condition of SNU-C5/5-FU. To examine whether LS-1 can induce apoptosis via the activation of TGF-ß signaling, the SNU-C5/5-FU cells were treated with LS-1 in the presence or absence of SB525334, a TGF-ßRI kinase inhibitor. SB525334 inhibited the effect of LS-1 on the apoptosis induction. These findings provide evidence demonstrating that the apoptosis-induction effect of LS-1 results from the activation of the TGF-ß pathway via the downregulation of CEA in SNU-C5/5-FU.

Clot-Targeted Antithrombotic Liposomal Nanomedicine Containing High Content of H2O2-Activatable Hybrid Prodrugs.

Liposomes have been extensively explored as drug carriers, but their clinical translation has been hampered by their low drug-loading content and premature leakage of drug payloads. It was reasoned that vesicle-forming prodrugs could be incorporated into the lipid bilayer at a high molar fraction and therefore serve as a therapeutic agent as well as a structural component in liposomal nanomedicine. Boronated retinoic acid (BORA) was developed as a prodrug, which can self-assemble with common lipids to form liposomes at a high molar fraction (40%) and release all-trans retinoic acid (atRA) and hydroxybenzyl alcohol (HBA) simultaneously, in response to hydrogen peroxide (H2O2). Here, we report fucoidan-coated BORA-incorporated liposomes (f-BORALP) as clot-targeted antithrombotic liposomal nanomedicine with H2O2-triggered multiple therapeutic actions. In the mouse model of carotid arterial thrombosis, f-BORALP preferentially accumulated in the injured blood vessel and significantly suppressed thrombus formation, demonstrating their potential as targeted antithrombotic nanomedicine. This study also provides valuable insight into the development of vesicle-forming and self-immolative prodrugs to exploit the benefits of liposomal drug delivery.

Nanoassemblies of Self-Immolative Boronate-Bridged Retinoic Acid Dimeric Prodrug as a Clot-Targeted Self-Deliverable Antithrombotic Nanomedicine.

All trans-retinoic acid (atRA) has potent anti-inflammatory and antiplatelet activity, but its clinical translation as an antithrombotic drug has been hampered by its low therapeutic efficacy. Here, we describe a facile and elegant strategy that converts atRA into systemically injectable antithrombotic nanoparticles. The strategy involves the dimerization of two atRA molecules using a self-immolative boronate linker that is cleaved specifically by hydrogen peroxide (H2O2) to release anti-inflammatory hydroxybenzyl alcohol (HBA), followed by dimerization-induced self-assembly to generate colloidally stable nanoparticles. The boronated atRA dimeric prodrug (BRDP) could form injectable nanoparticles in the presence of fucoidan that serves as an emulsifier and a targeting ligand to P-selectin overexpressed on the damaged endothelium. In response to H2O2, fucoidan-decorated BRDP (f-BRDP) nanoassemblies dissociate to release both atRA and HBA, while scavenging H2O2. In a mouse model of ferric chloride (FeCl3)-induced carotid arterial thrombosis, f-BRDP nanoassemblies target the thrombosed vessel and significantly inhibit thrombus formation. The results demonstrate that dimerization of atRA molecules via a boronate linker enables the formation of stable nanoassemblies with several benefits: high drug loading, drug self-delivery, on-demand multiple antithrombotic actions, and simple fabrication of nanoparticles. Overall, this strategy provides a promising expedient and practical route for the development of translational self-deliverable antithrombotic nanomedicine.

Self-deliverable and self-immolative prodrug nanoassemblies as tumor targeted nanomedicine with triple cooperative anticancer actions.

Stimulus-responsive self-assembling prodrug-based nanomedicine has emerged as a novel paradigm in controlled drug delivery. All-trans retinoic acid (RA), one of vitamin A metabolites, induces apoptotic cancer cell death, but its clinical applications are limited by weak anticancer efficacy. To fully maximize the therapeutic potential of RA, we exploited the unique chemistry of arylboronic acid which undergoes hydrogen peroxide (H2O2)-triggered degradation to release quinone methide (QM) that alkylates glutathione (GSH) to disrupt redox homeostasis and is also converted into hydroxybenzyl alcohol (HBA) to suppress the expression of vascular endothelial growth factor (VEGF). Here, we report that boronated retinoic acid prodrug (RABA) can be formulated into self-deliverable nanoassemblies which release both RA and QM in a H2O2-triggered self-immolative manner to exert cooperative anticancer activities. RABA nanoassemblies exert anticancer effects by inducing reactive oxygen species (ROS)-mediated apoptosis, eliciting immunogenic cell death (ICD) and suppressing angiogenic VEGF expression. The excellent anticancer efficacy of RABA nanoassemblies can be explained by benefits of self-assembling prodrug-based drug self-delivery and cooperative anticancer actions. The design strategy of RABA would provide a new insight into the rational design of self-deliverable and self-immolative boronated prodrug nanoassemblies for targeted cancer therapy.