27 MHz constant field dielectric warming of kidneys cryopreserved by vitrification

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-04-18 DOI:10.1016/j.cryobiol.2024.104893

Brian Wowk, John Phan, Roberto Pagotan, Erika Galvez, Gregory M. Fahy

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Abstract

Organs cryopreserved by vitrification are exposed to the lowest possible concentration of cryoprotectants for the least time necessary to successfully avoid ice formation. Faster cooling and warming rates enable lower concentrations and perfusion times, reducing toxicity. Since warming rates necessary to avoid ice formation during recovery from vitrification are typically faster than cooling rates necessary for vitrification, warming speed is a major determining factor for successful vitrification. Dielectric warming uses an oscillating electric field to directly heat water and cryoprotectant molecules inside organs to achieve warming that's faster and more uniform than can be achieved by heat conduction from the organ surface. This work studied 27 MHz dielectric warming of rabbit kidneys perfused with M22 vitrification solution. The 27 MHz frequency was chosen because its long wavelength and penetration depth are suitable for human organs, because it had an anticipated favorable temperature of maximum dielectric absorption in M22, and because it's an allocated frequency for industrial and amateur use with inexpensive amplifiers available. Previously vitrified kidneys were warmed from −100 °C by placement in a 27 MHz electric field formed between parallel capacitor plates in a resonant circuit. Power was varied during warming to maintain constant electric field amplitude between the plates. Maximum power absorption occurred near −70 °C, with a peak warming rate near 150 °C/min in 50 mL total volume with approximately 500 W power. After some optimization, it was possible to warm ∼13 g vitrified kidneys with unprecedentedly little injury from medullary ice formation and a favorable serum creatinine trend after transplant. Distinct behaviors of power absorption and system tuning observed as a function of temperature during warming are promising for non-invasive thermometry and future automated control of the warming process at even faster rates with user-defined temperature dependence.

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27 兆赫恒定场介质加热玻璃化冷冻保存的肾脏

通过玻璃化技术冷冻保存的器官接触尽可能低浓度的冷冻保护剂的时间最短，以成功避免冰的形成。较快的冷却和升温速度可降低浓度和灌注时间，从而减少毒性。由于玻璃化复苏过程中避免冰形成所需的升温速度通常快于玻璃化所需的降温速度，因此升温速度是玻璃化成功与否的主要决定因素。介电升温利用振荡电场直接加热器官内的水和低温保护剂分子，实现比器官表面热传导更快、更均匀的升温。这项工作研究了用 M22 玻璃化溶液灌注兔肾的 27 MHz 介电升温。之所以选择 27 MHz 频率，是因为它的长波长和穿透深度适用于人体器官，因为它具有 M22 最大介电吸收的预期有利温度，还因为它是工业和业余用途的分配频率，而且放大器价格低廉。将先前玻璃化的肾脏放置在谐振电路中平行电容器板之间形成的 27 兆赫电场中，从零下 100 摄氏度开始升温。在升温过程中改变功率以保持板间电场振幅恒定。最大功率吸收发生在-70 °C附近，峰值升温速率接近150 °C/分钟，总体积为50 mL，功率约为500 W。经过优化后，可以对 13 克玻璃化肾脏进行加热，髓质冰的形成对肾脏造成的损伤前所未有地小，而且移植后血清肌酐趋势良好。在升温过程中观察到的功率吸收和系统调谐随温度变化的不同行为，有望用于非侵入式温度测量和未来的自动控制升温过程，其速率甚至更快，并可由用户定义温度相关性。

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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