Kidney-specific drug targeting is an attractive strategy to reduce unwanted side effects and to enhance drug efficacy within the renal tissue. For this purpose a novel kidney-specific drug carrier was developed. The peptide sequence (KKEEE)3K triggers exceptional renal specificity at high accumulation rates. Micro-PET imaging studies of megalin-deficient mice indicate that the cellular endocytosis of this carrier is mediated by megalin. This assumption is supported by immunohistochemical analysis of FITC-labeled carrier peptide, which exclusively accumulated at the apical side of proximal tubule cells within the renal cortex. Scintigraphic studies of modified ciprofloxacin conjugated to (KKEEE)3K confirmed the excellent drug targeting potential of the peptide carrier. The conjugate accumulated entirely in the kidneys, revealing flawless redirection of ciprofloxacin, a compound that is mainly excreted by the liver. In conclusion, these results suggest the potential of (KKEEE)3K as a promising candidate for kidney-targeted drug delivery to proximal tubule cells.
The reactive metabolite methylglyoxal (MG) has been identified as mediator of pain. Scavenging of free MG and the prevention of MG-derived post-translational modifications may provide a useful therapeutic treatment. An arginine-rich, fatty acid coupled, cyclic peptide (CycK(Myr)R4E) with high proteolytic stability and prolonged circulation was developed for the scavenging of MG. It was shown to reduce the formation of albumin-MG adducts in vitro and prevented MG-induced pain by reducing plasma MG levels through the formation of peptide-MG adducts in vivo. CycK(Myr)R4E therefore presents a promising option for the treatment of pain and other diabetic complications associated with high MG levels.
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