Along with complications stemming from primary graft dysfunction (PGD), a significant shortage of available donor lungs has prevented lung transplantation from achieving widespread utilization as a treatment for end-stage lung disease. Despite a growing number of lung transplants taking place worldwide, the number of patients awaiting them is growing faster?prompting numerous efforts aimed at expanding the donor pool through aggressive donor management and innovative organ preservation strategies aimed primarily at improving transplant outcomes for ?marginal? lungs harvested after donor brain death (DBD). DBD Lung allografts are at increased risk of PGD due to the combination of hemodynamic injury and inflammatory upregulation that brain death causes in the donor lung. Recent studies have identified several strategies that successfully prevent and/or combat this injury and its deleterious post-transplant effects?including donor pre-treatment, delayed organ recovery, and ex-vivo lung perfusion (EVLP). However, advances in this area are limited by an incomplete understanding of the mechanisms by which DBD compromises graft viability. In response to this need and in accordance with the primary focus of this RFA, the proposed project will use an integrated imaging method which our lab has created for quantitatively measuring regional structural, functional and metabolic parameters of the lung in order to provide an early, objective assessment of organ quality prior to procurement. Using a combination of hyperpolarized (HP) gas-MRI and HP carbon-13 magnetic resonance spectroscopic imaging (MRSI), we will establish the early cellular dynamics of donor lung injury subsequent to brain death and track this injury? progression over time and in response to various treatment and preservation strategies. The first task of this project will be to use our combined imaging technique to establish an imaging profile of acute lung injury immediately following donor brain death in a rat model. Second, we will use these imaging parameters to identify an optimal window for organ recovery by tracking the progression of donor lung injury over time, both in the absence of and in response to several already proven pre-treatments. Third, we will use phosphorus and 13C MR spectra to evaluate metabolic activity in the donor lung during ex-vivo perfusion, whose parameters will have been suggested by our pre-harvest imaging of the organ. We will use the combination of our imaging parameters and histology to compare graft performance after transplantation among all cohorts and to evaluate the success of given therapeutic strategies in preventing PGD. Finally, we will repeat perform EVLP studies on several human lungs in order to assess the translational potential of our imaging technique and parameters.
This project seeks to use hyperpolarized 13C and gas-MRI to establish a set of functional, structural and metabolic imaging parameters capable of non-invasively assessing lung graft viability in brain dead donors. While transplantation is now an effective treatment for end-stage lung disease, there is still a major shortage of available lungs. An early and accurate assessment of lung quality would optimize recent attempts to expand the donor pool through donor pre-treatment and organ preservation.