Reusable bi-directional 3<i>ω</i> sensor to measure thermal conductivity of 100-<i>μ</i>m thick biological tissues

Lubner, Sean; Choi, Jeunghwan; Wehmeyer, Geoff; Waag, Bastian; Mishra, Vivek; Natesan, Harishankar; Bischof, John C.; Dames, Chris

doi:10.1063/1.4905680

Cited by 50 publications

(54 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…idealized theoretical calculation 17,23 with the experiment shows that the experimental measurements are consistent with the model trends, and suggest that with proper calibration can be used to measure thickness.…”

Section: Resultsmentioning

confidence: 68%

“…1(b,d). The exact analytical solution to this conduction problem is well known 12,17,35 . Thermal waves propagate and decay radially away from the heater and PD can be calculated using Eqn (1) …”

Section: Methodsmentioning

confidence: 99%

“…Figure 1 shows the basic concept of the supported 3ω method 17 . A periodic electrical current (~40 mA rms) of angular frequency 'ω ' is passed through the heater, I = I 0 sin ω t, between the leads I + and I-.…”

Section: Methodsmentioning

confidence: 99%

“…To avoid dehydration and/or evaporation of water content in the tissue, the sample was encapsulated on the sides and at the top by agar gel (0.5% by weight agarose powder dissolved in water at 65 °C and solidified overnight in a 4 °C refrigerator). The sample-agar gel complex is then covered by a plastic wrap to isolate the sample from evaporative cooling and sublimation which interfere with a consistent and correct measurement 17 . Importantly, in this system, water evaporation or ice sublimation from the tissue was negligible (weight change < 5%) during the measurement in Fig.…”

Section: Methodsmentioning

confidence: 99%

“…This technique has been commonly used to measure thermal conductivity of inorganic materials [13][14][15][16] . Recently, it has been modified to measure 'k' of biological tissues 17 and even cells 18 . The current article presents proof of principle data to show the ability of the sensor to give thermal conductivity for treatment planning and then extends the sensor use for other measurements relevant for monitoring.…”

mentioning

confidence: 99%

See 4 more Smart Citations

A micro-thermal sensor for focal therapy applications

et al. 2016

View full text Add to dashboard Cite

There is an urgent need for sensors deployed during focal therapies to inform treatment planning and in vivo monitoring in thin tissues. Specifically, the measurement of thermal properties, cooling surface contact, tissue thickness, blood flow and phase change with mm to sub mm accuracy are needed. As a proof of principle, we demonstrate that a micro-thermal sensor based on the supported "3ω" technique can achieve this in vitro under idealized conditions in 0.5 to 2 mm thick tissues relevant to cryoablation of the pulmonary vein (PV). To begin with "3ω" sensors were microfabricated onto flat glass as an idealization of a focal probe surface. The sensor was then used to make new measurements of 'k' (W/m.K) of porcine PV, esophagus, and phrenic nerve, all needed for PV cryoabalation treatment planning. Further, by modifying the sensor use from traditional to dynamic mode new measurements related to tissue vs. fluid (i.e. water) contact, fluid flow conditions, tissue thickness, and phase change were made. In summary, the in vitro idealized system data presented is promising and warrants future work to integrate and test supported "3ω" sensors on in vivo deployed focal therapy probe surfaces (i.e. balloons or catheters).Focal energy based therapies have a long history of use in the treatment of cancer, cardiovascular and neural disease [1][2][3] . As the technique evolves, there are increasingly thin and complex tissue anatomies where focal therapies and freezing are being applied that require sub mm monitoring accuracy to avoid debilitating side effects. For instance, cryogenic approaches to treatment of atrial fibrillation are increasingly being used in the pulmonary vein (PV) which is only 1-2 mm thick 4-7 . This treatment in thin PV often suffers from over and under-freezing suggesting a need for better monitoring. Unfortunately, traditional clinical imaging has difficulty monitoring at or below the mm scale, which is of the order of thickness of the PV itself. For this reason it is not surprising that in a pilot computed tomography (CT) study, we were unable to visualize the PV or the freezing process within it 8 . So, despite the past successes of clinical image guidance for cryoablation in cm sized tissues [9][10][11]

show abstract

Section: Resultsmentioning

confidence: 68%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

A micro-thermal sensor for focal therapy applications

et al. 2016

View full text Add to dashboard Cite

show abstract

Flexible and Stretchable 3ω Sensors for Thermal Characterization of Human Skin

Tian

Webb

et al. 2017

Adv Funct Materials

101

View full text Add to dashboard Cite

Characterization of the thermal properties of the surface and sub-surface structures of the skin can reveal the degree of hydration, the rate of blood flow in near-surface micro and macrovasculature, and other important physiological information of relevance to dermatological and overall health status. Here, we introduce a soft, stretchable thermal sensor, based on the so-called three omega (i.e. 3ω) method, for accurate characterization of the thermal conductivity and diffusivity of materials systems, such as the skin, that can be This article is protected by copyright. All rights reserved. 5 challenging to measure using established techniques. Experiments on skin at different body locations and under different physical states demonstrate the possibilities. Systematic studies establish the underlying principles of operation in these unusual systems, thereby allowing rational design and use of these types of devices, through combined investigations based on analytical modeling, experimental measurements and finite element analysis. The findings create broad opportunities for the use of 3ω methods in biology, with utility ranging from the integration with surgical tools or implantable devices to non-invasive uses in clinical diagnostics and therapeutics.

show abstract

Continuously‐Tunable and Ultrawide‐Range Thermal Regulator Based on Superaligned Carbon Nanotube Aerogels for Dynamic Thermal Management of Batteries and Buildings

Yu,

Dai,

Hong

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

Efficient heat transfer control is highly demanded for dynamic thermal management of equipment and buildings especially when the environmental temperature dramatically changes. Thermal switches, the current approach of heat transfer control, suffer from the issues of low switching ratios below eight and sharp state transition between “on” and “off”. Herein, a continuously‐tuned thermal regulator with an ultrahigh thermal‐conductivity change ratio of 43 based on superaligned carbon nanotube aerogel is reported, which works on the regulation of both thermal interfacial resistance and conduction pathways by compressive deformation‐induced microstructure evolution. This thermal regulator can stabilize the device temperature at 25 °C when the environmental temperature varies by 7 and 11 °C under the natural convection and forced convection conditions, respectively. Toward practical application, the thermal regulator with flexibility is wrapped around a cylindrical lithium‐ion battery to control the operation temperature within the optimal range of 20–40 °C for enhanced discharging performance even at an environmental temperature of −20 °C. Besides, by combining the thermal regulator with radiative cooling film, the house model temperature can be lowered by 2.7 °C during daytime and raised by 1.1 °C during nighttime compared with the bare one. This efficient thermal regulation approach offers an effective solution for practical thermal management.

show abstract

Reusable bi-directional 3ω sensor to measure thermal conductivity of 100-μm thick biological tissues

Cited by 50 publications

References 38 publications

A micro-thermal sensor for focal therapy applications

A micro-thermal sensor for focal therapy applications

Flexible and Stretchable 3ω Sensors for Thermal Characterization of Human Skin

Continuously‐Tunable and Ultrawide‐Range Thermal Regulator Based on Superaligned Carbon Nanotube Aerogels for Dynamic Thermal Management of Batteries and Buildings

Contact Info

Product

Resources

About