Thermal analysis in a triple-layered skin structure with embedded vasculature, tumor, and gold nanoshells
Abstract
© 2017 Elsevier Ltd Obtaining accurate temperature distributions in living tissue
related to hyperthermia skin cancer treatment without using an intruding sensor is
a challenge. Here, we report a mathematical model that can accurately determine the
temperature distribution in the tumor region and surrounding normal tissue. The model
is based on a modified Pennes’ equation for the bioheat transfer in a 3-D triple-layered
skin structure embedded with a vascular countercurrent network and a tumor appearing
in the subcutaneous region. The vascular network is designed based on the constructal
theory of multi-scale tree-shaped heat exchangers. The tumor is injected with gold
nanoshells in order to be heated quickly. The proposed model is implemented numerically
using a stable finite difference scheme. The method is demonstrated and tested by
an example.
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Journal articlePermalink
https://hdl.handle.net/10161/15195Published Version (Please cite this version)
10.1016/j.ijheatmasstransfer.2017.04.024Publication Info
(2017). Thermal analysis in a triple-layered skin structure with embedded vasculature, tumor,
and gold nanoshells. International Journal of Heat and Mass Transfer, 111. pp. 677-695. 10.1016/j.ijheatmasstransfer.2017.04.024. Retrieved from https://hdl.handle.net/10161/15195.This is constructed from limited available data and may be imprecise. To cite this
article, please review & use the official citation provided by the journal.
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Adrian Bejan
J.A. Jones Distinguished Professor of Mechanical Engineering
Professor Bejan was awarded the Benjamin Franklin Medal 2018 and the Humboldt Research
Award 2019. His research covers engineering science and applied physics: thermodynamics,
heat transfer, convection, design, and evolution in nature. He is ranked among the
top 0.01% of the most cited and impactful world scientists (and top 10 in Engineering
world wide) in the 2019 citations impact database created by Stanford University’s
John Ioannidis, in <a href="https://urldefen
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