磁纳米粒子对Vs55溶液反玻璃化等温结晶行为的影响

借助差示扫描量热仪(DSC)和低温显微系统,研究了磁纳米粒子对典型玻璃化溶液Vs55在反玻璃化过程中等温结晶行为的影响。结果表明:(1)磁纳米粒子经过羧酸(CA)和聚乙二醇(PEG)表面修饰后,对Vs55溶液的玻璃化转变温度(Tg)几乎没有影响,但对其反玻璃化转变温度(Td)和反玻璃化结晶焓(HTd)影响较大;(2)在Vs55的反玻璃化温区范围内(-85^-60℃),随着等温温度的升高和降温速率的增大,经CA修饰的磁纳米粒子均会显著促进Vs55的反玻璃化现象,在-85℃等温时的冰晶生长速率为0.37μm·s^(-1),-75℃等温时则为2.19μm·s^(-1),而当降温速率从2℃·min^(-1)增大到100℃·min^(-1)时(在-75℃等温结晶),其反玻璃化冰晶生长的速率由1.72μm·s^(-1)增大到3.54μm·s^(-1);(3)与Vs55相比,两种修饰均明显促进了其反玻璃化,在-80℃等温结晶时,Vs55溶液的生长速率为0,而CA和PEG修饰分别达到了1.04μm·s^(-1)和2.31μm·s^(-1);与CA修饰相比,PEG修饰后的磁纳米粒子更加促进了Vs55溶液的反玻璃化现象,在-85℃等温时的冰晶生长速率为0.62μm·s^(-1),而-75℃等温时则达到了6.25μm·s^(-1),这个结果也充分说明了磁纳米粒子表面修饰物质的不同必定会显著影响Vs55的反玻璃化结晶生长。

氧化石墨烯对VS55冻融过程结晶行为的影响

借助差示扫描量热仪(DSC)和低温显微系统,研究了升降温速率(5、10、25、50和100℃/min)和氧化石墨烯(GO)浓度(0.01、0.1、1和5 mg/ml)对VS55溶液降温过程结晶和升温过程冰晶再生长的影响。结果表明:(1)随着升降温速率的增加,VS55溶液体系在降温过程中的结晶焓Hf以及升温过程中的再结晶焓HTd都会减小;(2)对浓度为2.1 mol/L的VS55溶液进行降温时,GO浓度越大,其结晶焓Hf越大,且初始冻结温度显著提高;但对4.2 mol/L VS55降温时,其结晶焓Hf会随着GO浓度增加呈现出先减小后增大的特点;8.4 mol/L VS55已完全玻璃化,GO对其没有影响;(3)在升温过程中,GO浓度越高,VS55浓度越低,其溶液体系内冰晶再生长抑制程度越大,如GO浓度为5 mg/ml时,2.1 mol/L VS55溶液添加GO前后再结晶焓的差值ΔHTd为14.55 J/g,而4.2 mol/L VS55就显著降低到7.95 J/g,接近8.4 mol/L VS55的6.91 J/g。总体来看,GO对VS55溶液降温过程冰晶生长特点的影响主要取决于VS55浓度和GO浓度,但对复温过程反玻璃化或冰晶再生长特点的影响主要取决于VS55浓度、GO浓度以及升降温速率。

纳米粒子浓度等条件对VS55反玻璃化结晶的影响

借助低温显微镜系统,运用等温扫描和连续扫描法,对磁性纳米粒子浓度、等温温度以及降复温速率对低温保护剂VS55在反玻璃化过程中的结晶行为进行了观察.结果显示:随着磁性纳米粒子浓度和等温温度的增加,冰晶生长速率、初始尺寸及结晶密度整体上都增大,冰晶生长得到促进;对含有不同磁性纳米粒子浓度的VS55进行连续扫描,结果与等温扫描结论一致,添加磁性纳米粒子的溶液反玻璃化冰晶生长明显;降温速率增长至5℃/min时,冰晶初始尺寸和冰晶数量显著提高,生长速率也略有增加,5℃/min以上的降温速率对冰晶的影响差别不大;随着复温速率的增大,冰晶尺寸、生长速率都减小,冰晶数量减少.

Research on Ice Crystal Growth Inside the Vitrified Vs55 with Magnetic Nanoparticles During Devitrification by Cryomicroscopy

The effect of magnetic nanoparticles(mNPs) on the devitrification crystallization of typical vitrification solution Vs55 was systematically explored by differential scanning calorimetry(DSC) and cryomicroscope system. The results show tliat,(i) the mNPs coated by both carboxylic acid(CA) and polyethylene glycol(PEG) had little effect on the glass transition temperature(rg) of Vs55, but had significant effect on the devitrification transition temperature(7a) and devitrification enthalpy(Hrd),(ii) in the range of the devitrification area(-85- 0℃), the MNPs coated by CA can significantly accelerate the devitrification of Vs55 as the isothermal temperatures and the cooling rates increased, and the ice growth rate was 0.37 p.m/s at the isothermal temperature of-85 ℃, and was about 2.19 gm/s at -75℃. Also, the ice growth rates rose from 1.72 pm/s to 3.54 pm/s when the cooling rates were increased from 2 ℃/min to 100 ℃/min(at the isothennal temperature of -75℃),(iii) magnetic nanoparticles coated by both PEG and CA could promote the devitrification of Vs55, for instance, without any crystal growth inside Vs55 at the isothermal temperature of-80℃, but 1.04 and 2.31 gm/s for adding magnetic nanoparticles coated by CA and PEG, respectively. Compared with the samples coated by CA, PEG promoted the devitrification of Vs55 in a much more positive way, and the ice growth rates were 0.62 and 6.25 μm/s at the isothermal temperatures of -85 and -75 ℃, respectively. Tliese results indicate that the surface coating of MNPs could significantly affect tlie recrystallization of Vs55, and further work should be conducted in the future research.

基于CT图像低温保护剂在大鼠肾脏中扩散特性的研究

低温保护剂(CPA)被广泛应用于生物组织材料的低温保存,而评估低温保护剂在生物组织中加载的均匀性是生物组织冷冻保存的关键问题之一。本文以大鼠肾脏为研究对象,采用计算机断层扫描成像(CT)研究了不同浓度Vs55在不同温度下肾脏渗透的传质特性,并结合相关理论研究其有效扩散系数(Deff)。结果表明:加载浓度越高,扩散速率越快;Vs55渗透摩尔浓度为8.4 mol/L,加载温度为4、22、37℃时,扩散速率分别为1.77×10^-6、2.94×10^-6、3.93×10^-6 cm^2/s。同时,建立了Vs55在肾脏中的扩散模型并验证扩散速率的有效性,决定系数(R2)和平均相对偏差(MRE)的范围分别为0.960~0.993和3.07%~6.74%。