BACKGROUND: To evaluate the role of energy state in primary graft dysfunction, which is crucial in lung transplantation, we investigated the relationship between intrapulmonary high-energy phosphate compounds and reperfusion lung injury after cold preservation. METHODS: Using an isolated rat lung perfusion model with fresh rat blood as perfusate, rat lungs were exposed to various cold preservation periods (0, 6, 9, and 12 hr) and reperfused. RESULTS: We found that extending the preservation period exacerbated the pulmonary hemodynamics after reperfusion. The levels of intrapulmonary high-energy phosphate compounds did not change during cold preservation, but these levels after reperfusion decreased as the preservation period was prolonged. The pulmonary hemodynamics after reperfusion were inversely correlated with the intrapulmonary high-energy phosphate compound levels after reperfusion. Total adenine nucleotide and ATP were sensitive indicators of reperfusion lung injury after cold preservation. Energy charge was not a sensitive indicator. The decreased levels of intrapulmonary high-energy phosphate compounds after reperfusion following cold preservation period were partially caused by their decreased production. CONCLUSIONS: These results demonstrated that reperfusion lung injury after cold preservation was closely correlated with decreased levels of intrapulmonary high-energy phosphate compounds after reperfusion, although the levels of the intrapulmonary high-energy phosphate compounds did not change during cold preservation of up to 12 hr.
BACKGROUND: To evaluate the role of energy state in primary graft dysfunction, which is crucial in lung transplantation, we investigated the relationship between intrapulmonary high-energyphosphate compounds and reperfusion lung injury after cold preservation. METHODS: Using an isolated rat lung perfusion model with fresh rat blood as perfusate, rat lungs were exposed to various cold preservation periods (0, 6, 9, and 12 hr) and reperfused. RESULTS: We found that extending the preservation period exacerbated the pulmonary hemodynamics after reperfusion. The levels of intrapulmonary high-energyphosphate compounds did not change during cold preservation, but these levels after reperfusion decreased as the preservation period was prolonged. The pulmonary hemodynamics after reperfusion were inversely correlated with the intrapulmonary high-energyphosphate compound levels after reperfusion. Total adenine nucleotide and ATP were sensitive indicators of reperfusion lung injury after cold preservation. Energy charge was not a sensitive indicator. The decreased levels of intrapulmonary high-energyphosphate compounds after reperfusion following cold preservation period were partially caused by their decreased production. CONCLUSIONS: These results demonstrated that reperfusion lung injury after cold preservation was closely correlated with decreased levels of intrapulmonary high-energyphosphate compounds after reperfusion, although the levels of the intrapulmonary high-energyphosphate compounds did not change during cold preservation of up to 12 hr.
Authors: Robert D Bongard; Ke Yan; Raymond G Hoffmann; Said H Audi; Xiao Zhang; Brian J Lindemer; Mary I Townsley; Marilyn P Merker Journal: Free Radic Biol Med Date: 2013-08-01 Impact factor: 7.376
Authors: C Hanusch; K Nowak; I S Gill; P Törlitz; N Rafat; A M Mueller; K C Van Ackern; B Yard; G C Beck Journal: Clin Exp Immunol Date: 2007-05-22 Impact factor: 4.330
Authors: Qifeng Zhao; Ji Wu; Qingwang Hua; Zhiyong Lin; Leping Ye; Weixi Zhang; Guowei Wu; Jie Du; Jie Xia; Maoping Chu; Xingti Hu Journal: J Transl Med Date: 2016-03-24 Impact factor: 5.531