High accuracy thermal conductivity measurement of aqueous cryoprotective agents and semi-rigid biological tissues using a microfabricated thermal sensor

Liang, Xin; Sekar, Praveen K.; Zhao, Gang; Zhou, Xiaoming; Shu, Zhiquan; Huang, Zhongping; Ding, Weiping; Zhang, Qingchuan; Gao, Dayong

doi:10.1038/srep10377

Cited by 12 publications

(7 citation statements)

References 39 publications

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“…Thermal conductivity of sample solutions was measured using a micro thermal sensor developed by Liang, et al [38] and manufactured in the lab. The sensor works on the principle of Transient Hot Wire (THW).…”

Section: Measurement Of Thermal Conductivitymentioning

confidence: 99%

Development of a Novel Electromagnetic Rewarming Technology for the Cryopreservation of Stem Cells with Large Volume

Ren¹,

Shu²,

Pan³

et al. 2021

Novel Perspectives of Stem Cell Manufacturing and Therapies

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Applications of stem cells have been playing significant roles in scientific and clinical settings in the last few decades. The foundation of these approaches is successful cryopreservation of stem cells for future use. However, so far we can only cryopreserve stem cell suspension of small volumes in the order of 1 mL mostly due to the lack of an effective rewarming technique. Rapid and uniform rewarming has been approved to be beneficial, and sometimes, indispensable for the survival of cryopreserved stem cells, inhibiting ice recrystallization or devitrification. Unfortunately, the conventional water bath thawing method failed in providing the rapid and uniform rewarming. The conversion of electromagnetic (EM) energy into heat provides a possible solution to this problem. This chapter will focus on (1) analysis of the combined EM and heat transfer phenomenon in the rewarming of a biospecimen, (2) numerical investigation of the rewarming system, (3) practical setup of an EM resonance system, and (4) test of heating performance with large volume of cells.

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Section: Measurement Of Thermal Conductivitymentioning

confidence: 99%

Development of a Novel Electromagnetic Rewarming Technology for the Cryopreservation of Stem Cells with Large Volume

Ren¹,

Shu²,

Pan³

et al. 2021

Novel Perspectives of Stem Cell Manufacturing and Therapies

Self Cite

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“…Calibrations of temperature and heat flow were conducted before the Thermal Conductivity Assessment. The thermal conductivity measurement system for CPA solutions developed by Liang et al 26 consists of a digital multimeter (Keithley, Cleveland, OH, USA), a microfabricated thermal sensor, and a computer for data acquisition. The sensor works with the principle of a transient hot wire.…”

Section: ■ Experimental Detailsmentioning

confidence: 99%

Investigation of Electromagnetic Resonance Rewarming Enhanced by Magnetic Nanoparticles for Cryopreservation

et al. 2018

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The lack of an effective rewarming technique restricted the successful cryopreservation of organ or large tissues by vitrification. The conversion of electromagnetic (EM) energy into heat provides a possible solution for the rewarming process for the cryopreservation. In this work, an EM resonance rewarming system was set up with dynamic feedback control and power feeding optimization. In addition, we take advantage of magnetic nanoparticles (MNPs) to absorb magnetic field energy to further enhance the energy conversion efficiency. We achieved a >200 °C min −1 rewarming rate for tens of milliliters of cryopreserved samples. Besides, we also investigated the effect of nanoparticle size and concentration based on thermal properties by analyzing the contribution of nanoparticles and the utilization of field energy. The closed system reduced the possible concomitant side effects when increasing the number of nanoparticles or increasing the EM source power. With the remarkably low dosage of nanoparticles (0.1 mg mL −1 Fe) compared to that for other MNP-based rewarming applications, this study opens the door to new approaches for exploring novel techniques for tissue and organ preservation.

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“…13,14 A microfabricated thermal sensor is capable of approaching a spatial resolution of 150 μm in semirigid biological tissues. 15 However, this invasive method is not suitable for measuring the temperature in a living body because of the penetration. It is also difficult to determine the exact temperature in space and in time simultaneously upon scanning detection positions.…”

Section: Introductionmentioning

confidence: 99%

“…Miscellaneous temporally and spatially resolved thermometric methods can be employed in nonfluidic matrixes of different physical dimensions and in diverse time domains, such as the transient plane source method and the transient hot-wire (THW) method on the 1–100 mm scale within 1–100 s . The THW method with thermocouples has been used to measure the thermal conductivity of tissue materials such as pig organs with the spatial domain in roughly mm. , A microfabricated thermal sensor is capable of approaching a spatial resolution of 150 μm in semirigid biological tissues . However, this invasive method is not suitable for measuring the temperature in a living body because of the penetration.…”

Section: Introductionmentioning

confidence: 99%

Thermographic Detection and Analysis of the Temporal and Spatial Evolution of Temperature upon Optical Heating of Gold Nanorod Assembly Immobilized in Agar

Chu

2018

ACS Omega

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Photoexcitation of the longitudinal surface plasmon resonance band of gold nanorods (AuNRs) in the near-infrared region has been widely employed in photothermal therapy. Generally, the temperature evolution of the surface of the object of interest reflects the photothermal efficiency. However, the temperature in the object interior may be higher than required and cause unwanted damage to the healthy cells or tissues in the vicinity of the unhealthy areas. In this work, agar served as a biomimicking tissue, and 1 mm 3 AuNR agar assembly cubes were placed at different depths with respect to the agar surface and excited with an 808 nm continuous-wave laser or an 850 nm lightemitting diode light. The evolution of the surface temperature was monitored with an infrared thermographic camera and analyzed with a point heat source model. The concentric temperature change suggested that the sample was nonfluidic and that convection and mass flow could be excluded. The depths of the AuNR agar cubes could be determined and were consistent with the prepared depths. Thus, using the agar matrix and AuNRs with optical heating and monitoring, in combination with the point heat source model, is feasible for the analysis of the surface and interior temperature evolutions of the object and the further determination of the initial conditions of systems, such as the positions of the heat source, the injection power, and so on.

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High accuracy thermal conductivity measurement of aqueous cryoprotective agents and semi-rigid biological tissues using a microfabricated thermal sensor

Cited by 12 publications

References 39 publications

Development of a Novel Electromagnetic Rewarming Technology for the Cryopreservation of Stem Cells with Large Volume

Development of a Novel Electromagnetic Rewarming Technology for the Cryopreservation of Stem Cells with Large Volume

Investigation of Electromagnetic Resonance Rewarming Enhanced by Magnetic Nanoparticles for Cryopreservation

Thermographic Detection and Analysis of the Temporal and Spatial Evolution of Temperature upon Optical Heating of Gold Nanorod Assembly Immobilized in Agar

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