Latner Thoracic Surgery Research Laboratories, Toronto General Hospital Research Institute, University Health Network, Toronto, ON M5G 1L7, Canada.
Departments of Pharmacology & Toxicology and Psychiatry, The Canada Mitochondrial Network, University of Toronto, Toronto, ON M5S 1A8, Canada.
Sci Transl Med. 2021 Sep 15;13(611):eabf7601. doi: 10.1126/scitranslmed.abf7601.
Cold static preservation on ice (~4°C) remains the clinical standard of donor organ preservation. However, mitochondrial injury develops during prolonged storage, which limits the extent of time that organs can maintain viability. We explored the feasibility of prolonged donor lung storage at 10°C using a large animal model and investigated mechanisms related to mitochondrial protection. Functional assessments performed during ex vivo lung perfusion demonstrated that porcine lungs stored for 36 hours at 10°C had lower airway pressures, higher lung compliances, and better oxygenation capabilities, indicative of better pulmonary physiology, as compared to lungs stored conventionally at 4°C. Mitochondrial protective metabolites including itaconate, glutamine, and -acetylglutamine were present in greater intensities in lungs stored at 10°C than at 4°C. Analysis of mitochondrial injury markers further confirmed that 10°C storage resulted in greater protection of mitochondrial health. We applied this strategy clinically to prolong preservation of human donor lungs beyond the currently accepted clinical preservation limit of about 6 to 8 hours. Five patients received donor lung transplants after a median preservation time of 10.4 hours (9.92 to 14.8 hours) for the first implanted lung and 12.1 hours (10.9 to 16.5 hours) for the second. All have survived the first 30 days after transplantation. There was no grade 3 primary graft dysfunction at 72 hours after transplantation, and median post-transplant mechanical ventilation time was 1.73 days (0.24 to 6.71 days). Preservation at 10°C could become the standard of care for prolonged pulmonary preservation, providing benefits to both patients and health care teams.
在冰上(约 4°C)进行冷静态保存仍然是供体器官保存的临床标准。然而,在长时间储存过程中会发生线粒体损伤,这限制了器官能够维持活力的时间。我们使用大型动物模型探索了在 10°C 下长时间保存供体肺的可行性,并研究了与线粒体保护相关的机制。在离体肺灌注期间进行的功能评估表明,与传统在 4°C 下储存的肺相比,在 10°C 下储存 36 小时的猪肺具有更低的气道压力、更高的肺顺应性和更好的氧合能力,表明具有更好的肺生理学。在 10°C 下储存的肺中存在更多的线粒体保护代谢物,包括衣康酸、谷氨酰胺和乙酰谷氨酰胺。线粒体损伤标志物的分析进一步证实,10°C 储存可更大程度地保护线粒体健康。我们将这种策略应用于临床,将人类供体肺的保存时间延长至目前可接受的临床保存极限(约 6 至 8 小时)以上。5 名患者接受了供体肺移植,其中第一枚植入肺的中位保存时间为 10.4 小时(9.92 至 14.8 小时),第二枚植入肺的中位保存时间为 12.1 小时(10.9 至 16.5 小时)。所有患者在移植后 30 天内均存活。移植后 72 小时无 3 级原发性移植物功能障碍,中位机械通气时间为 1.73 天(0.24 至 6.71 天)。10°C 保存可能成为延长肺保存的标准护理,为患者和医疗保健团队带来益处。
