Use of X-ray Tomography to Map Crystalline and Amorphous Phases in Frozen Biomaterials

Bischof, John C.; Mahr, Bernd; Choi, Jeung Hwan; Behling, M.; Mewes, Dieter

doi:10.1007/s10439-006-9176-7

Cited by 37 publications

(16 citation statements)

References 28 publications

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“…Finding the minimum time for complete loading is important in order to avoid unnecessary toxicity from the CPA. Thus, we studied VS55 permeation kinetics experimentally with micro computed tomography (μCT) by modifying previous methods (23). We first imaged dilutions of VS55 by μCT to establish a calibration of VS55 concentration to Hounsfield Units (HU) (Fig.…”

Section: Resultsmentioning

confidence: 99%

Improved tissue cryopreservation using inductive heating of magnetic nanoparticles

et al. 2017

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Vitrification, a kinetic process of liquid solidification into glass, poses many potential benefits for tissue cryopreservation including indefinite storage, banking, and facilitation of tissue matching for transplantation. To date, however, successful rewarming of tissues vitrified in VS55, a cryoprotectant solution, can only be achieved by convective warming of small volumes on the order of one mL. Successful rewarming requires both uniform and fast rates in order to reduce thermal mechanical stress and cracks, and to prevent rewarming phase crystallization. Here we present a scalable nanowarming technology for 1 to 80 mL samples using radiofrequency-excited mesoporous silica coated iron oxide nanoparticles in VS55. Advanced imaging including Sweep Imaging with Fourier Transform and micro computed tomography were used to verify loading and unloading of VS55 and nanoparticles and successful vitrification of human dermal fibroblast cells, porcine arteries, and porcine aortic heart valve leaflet tissue. Nanowarming was then used to demonstrate uniform and rapid rewarming at > 130 °C/min in both physical (1 to 80 mL) and biological systems (1 to 50 mL). Nanowarming yielded viability that matched control and/or exceeded gold standard convective warming in 1 to 50 mL systems, and improved viability compared to slow warmed (crystallized) samples. Finally, biomechanical testing displayed no significant biomechanical property changes in blood vessel length or elastic modulus after nanowarming compared to untreated fresh control porcine arteries. In aggregate, these results demonstrate new physical and biological evidence that nanowarming can improve the outcome of vitrified cryogenic storage of tissues in larger sample volumes.

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Section: Resultsmentioning

confidence: 99%

Improved tissue cryopreservation using inductive heating of magnetic nanoparticles

et al. 2017

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“…The EIT could be integrated with the cryomacroscopy setup with minimal modifications. An additional possibility is the application of X-ray computerized tomography (CT) [48] to the study of vitrification. While CT represents an excellent possibility to trace crystallization and fracturing in an opaque domain, it presents new challenges associated with in situ investigation in practical conditions within a commercially available cooling chamber.…”

Section: Resultsmentioning

confidence: 99%

The scanning cryomacroscope – A device prototype for the study of cryopreservation

Feig

Rabin

2014

Cryogenics

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A new cryomacroscope prototype—a visualization device for the in situ analysis of cryopreserved biological samples—is presented in the current study. In order to visualize samples larger than the field of view of the optical setup, a scanning mechanism is integrated into the system, which represents a key improvement over previous cryomacroscope prototypes. Another key feature of the new design is in its compatibility with available top-loading controlled-rate cooling chambers, which eliminates the need for a dedicated cooling mechanism. The objective for the current development is to create means to generate a single digital movie of an experimental investigation, with all relevant data overlaid. The visualization capabilities of the scanning cryomacroscope are demonstrated in the current study on the cryoprotective agent dimethyl sulfoxide and the cryoprotective cocktail DP6. Demonstrated effects include glass formation, various regimes of crystallization, thermal contraction, and fracture formation.

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“…36,37 Commonly used calorimetric methods include differential scanning calorimetry (DSC) and differential thermal analysis (DTA); these techniques are used to create phase diagrams, quantify water transport through the plasma membranes, 38 and detect ice crystal growth within cells. 39 Magnetic resonance imaging (MRI) 40 and computer tomography (CT) 41,42 have been used to visualize three-dimensional ice crystal growth and permeation of cryoprotective agents within spatially extended specimens. Microscopic methods include cryomicroscopy, 43 directional solidification, 44 cryo electron microscopy, 45 and multiphoton microscopy.…”

Section: Characterizing Samples At Low Temperaturesmentioning

confidence: 99%

Storage of Human Biospecimens: Selection of the Optimal Storage Temperature

Hubel

Spindler

Skubitz

2014

Biopreservation and Biobanking

121

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Millions of biological samples are currently kept at low tempertures in cryobanks/biorepositories for long-term storage. The quality of the biospecimen when thawed, however, is not only determined by processing of the biospecimen but the storage conditions as well. The overall objective of this article is to describe the scientific basis for selecting a storage temperature for a biospecimen based on current scientific understanding. To that end, this article reviews some physical basics of the temperature, nucleation, and ice crystal growth present in biological samples stored at low temperatures (-20°C to -196°C), and our current understanding of the role of temperature on the activity of degradative molecules present in biospecimens. The scientific literature relevant to the stability of specific biomarkers in human fluid, cell, and tissue biospecimens is also summarized for the range of temperatures between -20°C to -196°C. These studies demonstrate the importance of storage temperature on the stability of critical biomarkers for fluid, cell, and tissue biospecimens.

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Use of X-ray Tomography to Map Crystalline and Amorphous Phases in Frozen Biomaterials

Cited by 37 publications

References 28 publications

Improved tissue cryopreservation using inductive heating of magnetic nanoparticles

Improved tissue cryopreservation using inductive heating of magnetic nanoparticles

The scanning cryomacroscope – A device prototype for the study of cryopreservation

Storage of Human Biospecimens: Selection of the Optimal Storage Temperature

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