Hydrodynamic delivery for the study, treatment and prevention of acute kidney injury

• Main Author: Corridon, Peter R.
• Other Authors: Atkinson, Simon
• Language: en_US
• Published: 2014
• Subjects: Acute kidney injury; Confocal microscopy; Gene delivery; Hydrodynamic delivery; Intravital two photon fluorescent microscopy; Renal gene therapy; Kidneys > Wounds and injuries > Research > Evaluation; Acute renal failure; Confocal fluorescence microscopy > Research > Evaluation > Analysis; Fluorescence microscopy > Research; Three-dimensional imaging in medicine > Research > Evaluation > Analysis; Kidneys > Diseases > Gene therapy; Kidneys > Diseases > Diagnosis; Kidneys > Pathophysiology; Gene therapy > Research; Image processing; Mitochondrial membranes > Research; Histology > Technique; Physiologic salines; Biophysics > Research > Evaluation; Gene targeting; Multiphoton excitation microscopy; Kidneys > Imaging; Transgenes > Expression
• Online Access: http://hdl.handle.net/1805/4603

Indiana University-Purdue University Indianapolis (IUPUI) === Advancements in human genomics have simultaneously enhanced our basic understanding of the human body and ability to combat debilitating diseases. Historically, research has shown that there have been many hindrances to realizing this medicinal revolution. One hindrance, with particular regard to the kidney, has been our inability to effectively and routinely delivery genes to various loci, without inducing significant injury. However, we have recently developed a method using hydrodynamic fluid delivery that has shown substantial promise in addressing aforesaid issues. We optimized our approach and designed a method that utilizes retrograde renal vein injections to facilitate widespread and persistent plasmid and adenoviral based transgene expression in rat kidneys. Exogenous gene expression extended throughout the cortex and medulla, lasting over 1 month within comparable expression profiles, in various renal cell types without considerably impacting normal organ function. As a proof of its utility we by attempted to prevent ischemic acute kidney injury (AKI), which is a leading cause of morbidity and mortality across among global populations, by altering the mitochondrial proteome. Specifically, our hydrodynamic delivery process facilitated an upregulated expression of mitochondrial enzymes that have been suggested to provide mediation from renal ischemic injury. Remarkably, this protein upregulation significantly enhanced mitochondrial membrane potential activity, comparable to that observed from ischemic preconditioning, and provided protection against moderate ischemia-reperfusion injury, based on serum creatinine and histology analyses. Strikingly, we also determined that hydrodynamic delivery of isotonic fluid alone, given as long as 24 hours after AKI is induced, is similarly capable of blunting the extent of injury. Altogether, these results indicate the development of novel and exciting platform for the future study and management of renal injury.