Decompression of inflammatory edema along with endothelial cell therapy expedites regeneration after renal ischemia-reperfusion injury.

Increased pressure due to postischemic edema aggravates renal ischemia-reperfusion injury (IRI). Prophylactic surgical decompression using microcapsulotomy improves kidney dysfunction after IRI. Supportive cell therapy in combination with microcapsulotomy might act synergistically protecting kidney function against IRI. The effects of therapeutic endothelial cell application alone and in combination with microcapsulotomy were investigated in a xenogenic murine model of 45-min warm renal ischemia. Renal function and perfusion were determined before as well as 2 and 18 days postischemia by (99m)Tc-MAG3 imaging and laser Doppler. Histological analysis included H&E stains and immunohistology for endothelial marker MECA-32, cell proliferation marker Ki-67, and macrophage marker F4/80. Histomorphological changes were quantified using a tubular injury score. Ischemia of 45 min led to severe tissue damage and a significant decrease in renal function and perfusion. Microcapsulotomy and cell therapy alone had no significant effect on renal function, while only surgical decompression significantly increased blood flow in ischemic kidneys. However, the combination of both microcapsulotomy and cell therapy significantly improved kidney function and perfusion. Combination therapy significantly reduced morphological injury of ischemic kidneys as determined by a tubular injury score and MECA-32 staining. Macrophage infiltration evidenced by F4/80 staining was significantly reduced. The Ki-67 proliferation index was increased, suggesting a regenerative environment. While microcapsulotomy and cell therapy alone have limited effect on renal recovery after IRI, combination therapy showed synergistic improvement of renal function, perfusion, and structural damage. Microcapsulotomy may create a permissive environment for cell therapy to work.

99mTc-MAG3 scintigraphy for the longitudinal follow-up of kidney function in a mouse model of renal ischemia-reperfusion injury.

BACKGROUND: Experimental models are essential tools in the development and evaluation of novel treatment options, but the preclinical model of renal ischemia-reperfusion injury is limited to the retrieval of (very) early functional data, leaving the pivotal long-term outcome unknown. The present study applies technetium-99m-mercapto-acetyl-tri-glycine [99mTc-MAG3] scintigraphy for the longitudinal follow-up examination of long-term kidney function after renal ischemia-reperfusion injury. METHODS: Unilateral warm ischemia was induced in scid beige mice by vascular clamping of the kidney hilum for 40 min. 99mTc-MAG3 scintigraphy was performed prior to injury, 8 and 14 days post ischemia. The fractional uptake rate [FUR] was calculated from scintigraphy data as a measure of renal clearance. RESULTS: FUR demonstrated a significant functional impairment of the ischemic kidney 8 and 14 days after injury (P < 0.05 vs. baseline), while contralateral non-ischemic kidneys showed no significant changes. In histological analysis, ischemic kidneys exhibited tubular dilatation and cytoplasmic degeneration as signs of hypoxia without any evidence for necrosis. CONCLUSIONS: FUR enables the detection of renal dysfunction and longitudinal long-term follow-up examination in the same individual. Our model may facilitate preclinical therapy evaluation for the identification of effective renoprotective therapies.

The intrinsic renal compartment syndrome: new perspectives in kidney transplantation.

PURPOSE: Inflammatory edema after ischemia-reperfusion may impair renal allograft function after kidney transplantation. This study examines the effect of edema-related pressure elevation on renal function and describes a simple method to relieve pressure within the renal compartment. METHODS: Subcapsular pressure at 6, 12, 24, 48 hr, and 18 days after a 45 min warm ischemia was determined in a murine model of renal ischemia-reperfusion injury. Renal function was measured by Tc-MAG3 scintigraphy and laser Doppler perfusion. Structural damage was assessed by histologic analysis. As a therapeutic approach, parenchymal pressure was relieved by a standardized circular 0.3 mm incision at the lower pole of the kidney capsule. RESULTS: Compared with baseline (0.9+/-0.3 mm Hg), prolonged ischemia was associated with a sevenfold increase in subcapsular pressure 6 hr after ischemia (7.0+/-1.0 mm Hg; P<0.001). Pressure levels remained significantly elevated for 24 hr. Without therapy, a significant decrease in functional parameters was found with considerably reduced tubular excretion rate (33+/-3.5%, P<0.001) and renal perfusion (64.5+/-6.8%, P<0.005). Histologically, severe tissue damage was found. Surgical pressure relief was able to significantly prevent loss of tubular excretion rate (62.5+/-6.8%, P<0.05) and renal blood flow (96.2+/-4.8%; P<0.05) and preserved the integrity of renal structures. CONCLUSIONS: Our data support the hypothesis of the existence of a renal compartment syndrome as a consequence of ischemia-reperfusion injury. Surgical pressure relief effectively prevented functional and structural renal impairment, and we speculate that this approach might be of value for improving graft function after renal transplantation.