Individual and Combined Impact of Oxygen and Oxygen Transporter Supplementation During Kidney Machine Preservation in a Porcine Preclinical Kidney Transplantation Model

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2019 Apr 26

PMID 31018558

Citations 16

Authors

Abdelsalam Kasil

Sebastien Giraud

Pierre Couturier

Akbar Amiri

Jerome Danion

Gianluca Donatini

Xavier Matillon

Thierry Hauet

Lionel Badet

Affiliations

Soon will be listed here.

Abstract

Marginal kidney graft preservation in machine perfusion (MP) is well-established. However, this method requires improvement in order to mitigate oxidative stress during ischemia-reperfusion, by using oxygenation or an O carrier with anti-oxidant capacities (hemoglobin of the marine worm; M101). In our preclinical porcine (pig related) model, kidneys were submitted to 1h-warm ischemia, followed by 23 h hypothermic preservation in Waves MP before auto-transplantation. Four groups were studied: W (MP without 100%-O2), W-O (MP with 100%-O2; also called hyperoxia), W-M101 (MP without 100%-O2 + M101 2 g/L), W-O + M101 (MP with 100%-O2 + M101 2 g/L) ( = 6/group). Results: Kidneys preserved in the W-M101 group showed lower resistance, compared to our W group. During the first week post-transplantation, W-O and W-M101 groups showed a lower blood creatinine and better glomerular filtration rate. KIM-1 and IL-18 blood levels were lower in the W-M101 group, while blood levels of AST and NGAL were lower in groups with 100% O2. Three months after transplantation, fractional excretion of sodium and the proteinuria/creatinuria ratio remained higher in the W group, creatininemia was lower in the W-M101 group, and kidney fibrosis was lower in M101 groups. We concluded that supplementation with M101 associated with or without 100% O2 improved the Waves MP effect upon kidney recovery and late graft outcome.

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