Heat Transport by Countercurrent Blood Vessels in the Presence of an Arbitrary Temperature GradientSource: Journal of Biomechanical Engineering:;1990:;volume( 112 ):;issue: 002::page 207Author:J. W. Baish
DOI: 10.1115/1.2891173Publisher: The American Society of Mechanical Engineers (ASME)
Abstract: This paper presents a three-dimensional analysis of the temperature field around a pair of countercurrent arteries and veins embedded in an infinite tissue that has an arbitrary temperature gradient along the axes of the vessels. Asymptotic methods are used to show that such vessels are thermally similar to a highly conductive fiber in the same tissue. Expressions are developed for the effective radius and thermal conductivity of the fiber so that it conducts heat at the same rate that the artery and vein together convect heat and so that its local temperature equals the mean temperature of the vessels. This result allows vascular tissue to be viewed as a composite of conductive materials with highly conductive fibers replacing the convective effects of the vasculature. By characterizing the size and thermal conductivity of these fibers, well-established methods from the study of composites may be applied to determine when an effective conductive model is appropriate for the tissue and vasculature as a whole.
keyword(s): Heat , Blood vessels , Temperature gradients , Biological tissues , Fibers , Temperature , Vessels , Composite materials AND Thermal conductivity ,
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| contributor author | J. W. Baish | |
| date accessioned | 2017-05-08T23:32:06Z | |
| date available | 2017-05-08T23:32:06Z | |
| date copyright | May, 1990 | |
| date issued | 1990 | |
| identifier issn | 0148-0731 | |
| identifier other | JBENDY-25858#207_1.pdf | |
| identifier uri | http://yetl.yabesh.ir/yetl/handle/yetl/106596 | |
| description abstract | This paper presents a three-dimensional analysis of the temperature field around a pair of countercurrent arteries and veins embedded in an infinite tissue that has an arbitrary temperature gradient along the axes of the vessels. Asymptotic methods are used to show that such vessels are thermally similar to a highly conductive fiber in the same tissue. Expressions are developed for the effective radius and thermal conductivity of the fiber so that it conducts heat at the same rate that the artery and vein together convect heat and so that its local temperature equals the mean temperature of the vessels. This result allows vascular tissue to be viewed as a composite of conductive materials with highly conductive fibers replacing the convective effects of the vasculature. By characterizing the size and thermal conductivity of these fibers, well-established methods from the study of composites may be applied to determine when an effective conductive model is appropriate for the tissue and vasculature as a whole. | |
| publisher | The American Society of Mechanical Engineers (ASME) | |
| title | Heat Transport by Countercurrent Blood Vessels in the Presence of an Arbitrary Temperature Gradient | |
| type | Journal Paper | |
| journal volume | 112 | |
| journal issue | 2 | |
| journal title | Journal of Biomechanical Engineering | |
| identifier doi | 10.1115/1.2891173 | |
| journal fristpage | 207 | |
| journal lastpage | 211 | |
| identifier eissn | 1528-8951 | |
| keywords | Heat | |
| keywords | Blood vessels | |
| keywords | Temperature gradients | |
| keywords | Biological tissues | |
| keywords | Fibers | |
| keywords | Temperature | |
| keywords | Vessels | |
| keywords | Composite materials AND Thermal conductivity | |
| tree | Journal of Biomechanical Engineering:;1990:;volume( 112 ):;issue: 002 | |
| contenttype | Fulltext |