posted on 2022-04-08, 21:06authored byWeimin Tang, Sudipta Panja, Chinmay M. Jogdeo, Siyuan Tang, Ao Yu, David Oupický
Acute kidney injury (AKI) is a global
healthcare burden characterized
by rapid loss of renal function and high morbidity and mortality.
Chemokine receptor CXCR4 participates in the renal infiltration of
immune cells following injury and in local inflammatory enhancement.
Injured renal tubule cells overexpress CXCR4, which could be used
as a target for improved drug delivery in AKI. Plerixafor is a small-molecule
CXCR4 antagonist that has shown beneficial effects against AKI and
has been previously developed into a polymeric analog (polymeric plerixafor,
PP). With the goal of gaining a better understanding of how overall
charge and hydrophilicity affect renal accumulation of PP, we have
synthesized PP copolymers containing hydroxyl, carboxyl, primary amine,
and alkyl moieties using Michael-type addition copolymerization. All
synthesized copolymers showed excellent CXCR4-binding and inhibiting
ability in vitro and improved cellular uptake in hypoxia-reoxygenation
stimulated mouse tubule cells. Analysis of serum protein binding revealed
that polymers with hydroxyl group modification showed the least amount
of protein binding. Biodistribution of the polymers was tested in
a unilateral ischemia reperfusion-induced AKI mouse model. The results
showed significant differences in accumulation in the injured kidneys
depending on the net charge and hydrophilicity of the polymers. The
findings of this study will guide the development of polymeric drug
carriers for targeted delivery to injured kidneys for better AKI therapy.