The impact of heart valve and partial heart transplant models on the development of banking methods for tissues and organs: A concise review

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Andrew D. Vogel , Rebecca Suk , Christa Haran , Patrick G. Dickinson , Kristi L. Helke , Marc Hassid , David C. Fitzgerald , Joseph W. Turek , Kelvin G.M. Brockbank , Taufiek Konrad Rajab
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Abstract

Cryopreserved human heart valves fill a crucial role in the treatment for congenital cardiac anomalies, since the use of alternative mechanical and xenogeneic tissue valves have historically been limited in babies. Heart valve models have been used since 1998 to better understand the impact of cryopreservation variables on the heart valve tissue components with the ultimate goals of improving cryopreserved tissue outcomes and potentially extrapolating results with tissues to organs. Cryopreservation traditionally relies on conventional freezing, employing cryoprotective agents, and slow cooling to sub-zero centigrade temperatures; but it is plagued by the formation of ice crystals and cell damage upon thawing. Researchers have identified ice-free vitrification procedures and developed a new rapid warming method termed nanowarming. Nanowarming is an emerging method that utilizes targeted application of energy at the nanoscale level to rapidly rewarm vitrified tissues, such as heart valves, uniformly for transplantation. Vitrification and nanowarming methods hold great promise for surgery, enabling the storage and transplantation of tissues for various applications, including tissue repair and replacement. These innovations have the potential to revolutionize complex tissue and organ transplantation, including partial heart transplantation. Banking these grafts addresses organ scarcity by extending preservation duration while preserving biological activity with maintenance of structural fidelity. While ice-free vitrification and nanowarming show remarkable potential, they are still in early development. Further interdisciplinary research must be dedicated to exploring the remaining challenges that include scalability, optimizing cryoprotectant solutions, and ensuring long-term viability upon rewarming in vitro and in vivo.

心脏瓣膜模型对开发组织和器官库方法的影响:简明综述。
冷冻保存的人类心脏瓣膜在治疗先天性心脏畸形方面发挥着至关重要的作用,因为替代机械瓣膜和异种组织瓣膜在婴儿中的使用一直受到限制。自 1998 年以来,人们一直在使用心脏瓣膜模型来更好地了解冷冻保存变量对心脏瓣膜组织成分的影响,最终目的是改善冷冻保存组织的结果,并有可能将组织结果推广到器官。冷冻保存传统上依靠传统的冷冻方法,使用冷冻保护剂,缓慢冷却到零摄氏度以下;但这种方法存在解冻时形成冰晶和细胞损伤的问题。研究人员发现了无冰玻璃化程序,并开发出一种新的快速升温方法,称为纳米升温。纳米加温是一种新兴方法,它利用纳米级能量的定向应用,快速均匀地重新加热玻璃化组织(如心脏瓣膜),以便进行移植。玻璃化和纳米加热方法在外科手术中大有可为,可储存和移植组织用于各种用途,包括组织修复和置换。这些创新技术有可能彻底改变复杂的组织和器官移植,包括部分心脏移植。将这些移植物存入银行可延长保存时间,同时保持生物活性和结构保真度,从而解决器官稀缺的问题。虽然无冰玻璃化和纳米升温技术显示出巨大的潜力,但它们仍处于早期开发阶段。进一步的跨学科研究必须致力于探索剩余的挑战,包括可扩展性、优化低温保护剂解决方案以及确保体外和体内回温后的长期存活率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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