Clinically translatable gold nanozymes with broad spectrum antioxidant and anti-inflammatory activity for alleviating acute kidney injury.

Rationale: Acute kidney injury (AKI) is associated with aberrant generation of oxidative species and inflammation, leading to high mortality of in-hospitalized patients. Although N-acetylcysteine (NAC) showed positive effects in alleviating contrast-induced AKI, the clinical applications are strongly restrained due to the low bioavailability, low renal accumulation, short renal retention time, and high dosage-induced toxicity. Methods: We addressed the clinical dilemma of NAC by developing ultrasmall gold nanoclusters (1-2 nm) capped with NAC (denoted as Au NCs-NAC) as a nanozyme-based antioxidant defense system for AKI alleviation. Rhabdomyolysis-induced AKI mice model was developed, and the same dose of free NAC (as a control) and NAC onto Au NCs (Au NCs-NAC) was used for in vivo investigation of AKI restoration. Results: The as-developed gold nanozyme exhibited high bioavailability and good physicochemical stability as compared to NAC. Meanwhile, Au NCs-NAC showed broad-spectrum antioxidant activity of Au NCs-NAC, offering in vitro renoprotective effects, as well as macrophages by relieving inflammation under hydrogen peroxide or lipopolysaccharide stimulation. Notably, owing to the smaller size than kidney threshold (5.5 nm), Au NCs-NAC displayed preferential renal enrichment (< 2 h) and longer retention (> 24 h) in AKI mice as revealed by fluorescence imaging, thereby largely enhancing the restoration of renal function in AKI mice than free NAC by protecting the kidneys from oxidative injury and inflammation without systemic toxicity, as demonstrated by tissues staining, inflammatory cytokines and biomarkers detection, and mice survival rate. Conclusion: Owing to the synergistic anti-inflammatory/antioxidative effects, and enhanced bioavailability and renal accumulation/retention, Au NCs-NAC displayed far superior therapeutic performance than NAC alone. This work will facilitate the development of high-performance antioxidative nanoplatforms, as well as overcome the clinical limitations of small molecular drugs for AKI treatment and other inflammatory diseases.

Biodegradable Self-Assembled Ultrasmall Nanodots as Reactive Oxygen/Nitrogen Species Scavengers for Theranostic Application in Acute Kidney Injury.

Acute kidney injury (AKI) is frequently triggered by abundant reactive oxygen/nitrogen species (RONS) and leads to high morbidity and mortality in clinic. Unfortunately, the current clinical treatment options are only limited to supportive care, and hence, the development of nano-antioxidants with high kidney enrichment is an attractive novel strategy for AKI management. Herein, self-assembled ultrasmall nanodots are reported that consist of iron ion, gallic acid, and polyvinylpyrrolidone (denoted as FGP nanodots) as broad-spectrum RONS scavengers to alleviate both glycerinum- and cis-platinum- induced AKI in mice. Ultrasmall FGP nanodots (≈3.5 nm) offer efficient protection in vitro and reduce cellular apoptosis after H2 O2 stimulation by eliminating various RONS including hydroxyl radical (·OH), superoxide anion (·O2- ), nitric oxide (NO), and peroxynitrite (ONOO- ), etc. In vivo duplex magnetic resonance/fluorescence imaging demonstrates preferential accumulation of FGP nanodots in the kidneys with rapid renal clearance through urine. Importantly, FGP nanodots exhibit remarkable RONS consumption in vivo with enhanced biocompatibility and biodegradability, resulting in superior therapeutic effect than small molecule drug (Amifostine) in two AKI mouse models. This study presents the promising potential of ultrasmall self-assembled FGP nanodots as imaging contrast agent and broad-spectrum antioxidant nanomedicine for AKI theranotics.