A fully conjugated blood vessel network model (FCBVNM) for calculating tissue temperatures has been developed, tested, and studied. This type of model represents a more fundamental approach to modeling temperatures in tissues than do the generally used approximate equations such as the Pennes’ BHTE or effective thermal conductivity equations. As such, this type of model can be used to study many important questions at a more basic level. For example, in the particular hyperthermia application studied herein, a simple vessel network model predicts that the role of counter current veins is minimal and that their presence does not significantly affect the tissue temperature profiles: the arteries, however, removed a significant fraction of the power deposited in the tissue. These more fundamental models can also be used to check the validity of approximate equations. For example, using the present simple model, when the temperatures calculated by the FCBVNM are used for comparing predictions from two approximation equations (a simple effective thermal conductivity and a simple Pennes’ bio-heat transfer equation formulation of the same problem) it is found that the Pennes’ equation better approximates the FCBVNM temperatures than does the keff model. These results also show that the “perfusion” value (W˙) in the Pennes’ BHTE is not necessarily equal to the “true” tissue perfusion (P˙) as calculated from mass flow rate considerations, but can be greater than, equal to, or less than that value depending on (1) how many vessel levels are modeled by the BHTE, and (2) the “true” tissue perfusion magnitude. This study uses a simple, generic vessel network model to demonstrate the potential usefulness of such fully conjugated vessel network models, and the associated need for developing and applying more complicated and realistic vascular network models. As more realistic vascular models (vessel sizes, orientations, and flow rates) are developed, the predictions of the fully conjugated models should more closely model and approach the true tissue temperature distributions, thus making these fully conjugated models more accurate and valuable tools for studying tissue heat transfer processes.

Issue Section:
Technical Papers
Topics:
Biological tissues, Heat transfer, Network models, Vessels, Temperature, Flow (Dynamics), Thermal conductivity, Approximation, Bioheat transfer, Blood vessels, Modeling, Temperature distribution, Temperature profiles
1.
Baish
J. W.
,
1990
, “
Heat Transport by Counter Current Blood Vessels in the Presence of an Arbitrary Temperature Gradient
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
112
, pp.
207
211
.
2.
Baish
J. W.
,
Ayyaswamy
P. S.
, and
Foster
K. R.
,
1986
a, “
Small-Scale Temperature Fluctuations in Perfused Tissue During Local Hyperthermia
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
108
, pp.
246
260
.
3.
Baish
J. W.
,
Ayyaswamy
P. S.
, and
Foster
K. R.
,
1986
b, “
Heat Transport Mechanisms in Vascular Tissues: A Model Comparison
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
108
, pp.
324
330
.
4.
Baish
J. W.
,
Foster
K. R.
, and
Ayyaswamy
P. S.
,
1986
c, “
Perfused Phantom Models of Microwave Irradiated Tissue
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
108
, pp.
239
245
.
5.
Charney
C. K.
, and
Levin
R. C.
,
1988
, “
Heat Transfer Normal to Paired Arterioles and Venules Embedded in Perfused Tissue During Hyperthermia
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
110
, pp.
277
282
.
6.
Chato
J. C.
,
1980
, “
Heat Transfer to Blood Vessels
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
102
, pp.
110
118
.
7.
Chen
M. M.
, and
Holmes
K. R.
,
1980
, “
Microvascular Contributions in Tissue Heat Transfer
,”
Annals of the New York Academy of Science
, Vol.
335
, pp.
137
150
.
8.
Chen, Z. P., 1989, “A Three Dimensional Treatment Planning Program for Hyperthermia,” Ph.D. dissertation, University of Arizona, Tucson, AZ.
9.
Chen
Z. P.
, and
Roemer
R. B.
,
1992
, “
The Effects of Large Blood Vessels on Temperature Distributions During Simulated Hyperthermia
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
114
, pp.
473
481
.
10.
Chen
Z. P.
, and
Roemer
R. B.
,
1993
, “
Improved Cartesian Coordinate Finite Difference Simulations of Small Cylindrical Objects
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
115
, pp.
119
122
.
11.
Crezee
J.
, and
Lagendijk
J. J. W.
,
1990
, “
Experimental Verification of Bio-Heat Transfer Theories: Measurement of Temperature Profiles Around Large Artificial Vessels in Perfused Tissues
,”
Phys. of Med. Bio.
, Vol.
35
, pp.
905
923
.
12.
Green, H. D., 1944, “Circulation, Physical Principles,” Medical Physics, O. Glasser ed., The Year Book Publishers, Inc., Chicago, IL, 208–252.
13.
Huang, H. W., 1992, “Simulation of Large Vessels in Hyperthermia Therapy,” M.S. thesis, University of Arizona, Tucson, AZ.
14.
Huang
H.
,
Chan
C.
, and
Roemer
R. B.
,
1994
, “
Analytical Solutions of Pennes Bio-Heat Transfer Equation With a Blood Vessel
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
116
, pp.
208
212
.
15.
Jiji
L. M.
,
Weinbaum
S.
, and
Lemons
D. E.
,
1984
, “
Theory and Experiment for the Effect of Vascular Microstructure on Surface Tissue Heat Transfer— Part II: Model Formulation and Solution
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
106
, pp.
331
341
.
16.
Lagendijk, J., and Mooibroek, J., 1986, “Hyperthermia Treatment Planning,” Recent Results in Cancer Research, Locoregional High-Frequency Hyperthermia and Temperature Measurement, G. Bruggmoser, W. Hinkelbein, R. Enggelhardt, and M. Wannenmacher eds., Springer-Verlag, Berlin, Vol. 101, pp. 119–131.
17.
Lapidus, L., and Pinder, G. F., 1982, Numerical Solution of Partial Differential Equations in Science and Engineering, Wiley-Interscience Publication, New York.
18.
Moros
E.
,
Dutton
A.
,
Roemer
R. B.
,
Burton
M.
, and
Hynynen
K.
,
1993
, “
Experimental Evaluation of Two Thermal Models Using Hyperthermia in Muscle In Vivo
,”
Int. J. Hyperthermia
, Vol.
9
, pp.
581
598
.
19.
Moros, E. G., 1990, “Experimental Evaluation of Scanned Focussed Ultrasound Hyperthermia Models in Canine Muscle In Vivo,” Ph.D. dissertation, University of Arizona, Tucson, AZ.
20.
Myrhage, R., 1977, “Microvascular Supply of Skeletal Muscle Fibres. A Microangiographic, Histochemical and Intravital Microscopic Study of the Hind Limb Muscles in Rat, Rabbit and Cat,” Acta Orthopaedica Scandinavica, Supplement 168.
21.
Myrhage
R.
, and
Eriksson
E.
,
1980
, “
Vascular Arrangements in the Hind Limb Muscles of the Cat
,”
Journal of Anatomy
, Vol.
131
, pp.
1
17
.
22.
Pennes
H. H.
,
1948
, “
Analysis of Tissue and Arterial Blood Temperatures in the Resting Human Forearm
,”
Journal of Applied Physiology
, Vol.
1
, pp.
93
122
.
23.
Rawnsley
R.
,
Roemer
R. B.
, and
Dutton
A.
,
1994
, “
The Simulation of Large Vessel Effects in Experimental Hyperthermia
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
116
, pp.
256
262
.
24.
Roemer, R. B., 1990, “Thermal Dosimetry,” Thermal Dosimetry and Treatment Planning, M. Gautherie, ed., Springer-Verlag, Berlin.
25.
Roemer, R. B., and Dutton, A. W., Derivation of a Simple Convective Energy Balance Equation for Tissue. (In preparation 1994).
26.
Roemer, R. B., Moros, E. M., and Hynynen, K., 1989, “A Comparison of Bio-Heat Transfer and Effective Conductivity Equation Predictions to Experimental Hyperthermia Data,” Bioheat Transfer Applications in Hyperthermia, Emerging Horizons in Instrumentation and Modeling, R. Roemer, J. McGrath, H. F. Bowman, eds., ASME, New York, NY, pp. 11–15.
27.
Sekins, K. M., and Emery, A., 1982, “Thermal Science for Physical Medicine,” Therapeutic Heat and Cold, J. Lehmann, ed., Williams and Wilkens, Baltimore, pp. 70–132.
28.
Sekins
K. M.
,
Lehmann
J. F.
,
Esselmann
P.
,
Dundore
D.
,
Emery
A. F.
,
deLateur
B. J.
, and
Nelp
W. B.
,
1984
, “
Local Muscle Blood Flow and Temperature Responses to 915 MHz Diathermy as Simultaneously Measured and Numerically Predicted
,”
Arch. Phys. Med. Rehabil.
, Vol.
65
, pp.
1
7
.
29.
Weinbaum
S.
,
Jiji
L. M.
, and
Lemons
D. E.
,
1984
, “
Theory and Experiment for the Effect of Vascular Microstructure on Surface Tissue Heat Transfer—Part I: Anatomical Foundation and Model Conceptualization
,”
ASME JOURNAL OF BIOMECHANICAL ENGINEERING
, Vol.
106
, pp.
321
330
.
30.
Whitmore, R. L., 1968, Rheology of the Circulation, Pergamon Press, New York, NY.
31.
Williams, W., 1990, “A Structural Model of Heat Transfer Due to Blood Vessels in Living Tissue,” Ph.D. dissertation, University of Arizona, Tucson, AZ.
This content is only available via PDF.
Copyright © 1996
 by The American Society of Mechanical Engineers
You do not currently have access to this content.