The effects of a thermally-significant blood vessel, simulated by an embedded acrylic tube, 4.8 mm outer diameter, on the freezing field caused by a surface cryoprobe were studied experimentally in a tissue phantom. The flat, 15 mm diameter, circular cryoprobe was operated at a constant cooling rate of 8°C/min by liquid nitrogen down to 160°C. Water flow rates of 30 and 100 ml/min, at a constant temperature of 32.5°C, were maintained in the embedded tube. The latter flow rate is typical to the lower range of blood flows in large arteries in the human body. The phase changing medium (PCM) used was a 30/70% by volume mashed potatoes flakes–water solution. Temperature measurements inside the PCM were performed in one plane perpendicular to the embedded tube, relative to which the cryoprobe was placed at 5 locations in separate experiments. This novel experimental method reduced the perturbation caused by the thermocouple junctions while facilitating rather detailed measurements of the temperature fields developing in the PCM. Results show the development of two hump-like formations on either side of the embedded tube. Freezing was retarded in the region away from the surface cryoprobe and under the tube. This accentuated the dominance of the axial effects, due to the embedded tube, over the radial ones due to the cryoprobe. Results of this study should be considered in designing protocols of cryosurgical procedures performed in the vicinity of thermally-significant blood vessels.

Issue Section:
Fluids/Heat/Transport
Keywords:
biothermics, freezing, probes, phantoms, blood vessels, haemodynamics, thermocouples, surgery, temperature measurement, biomedical measurement
Topics:
Biological tissues, Blood vessels, Freezing, Heat, Phantoms, Temperature, Thermocouples, Water, Flow (Dynamics), Junctions
1.
Shepherd
,
J.
, and
Dawber
,
R. P. R.
,
1981
, “
The Historical and Scientific Basis of Cryosurgery
,”
Clin. Exp. Dermatol.
,
7
, pp.
321
328
.
2.
Gage
,
A. A.
,
1992
, “
Progress in Cryosurgery
,”
Cryobiology
,
29
, pp.
300
304
.
3.
Orpwood
,
R. D.
,
1981
, “
Biophysical and Engineering Aspects of Cryosurgery
,”
Phys. Med. Biol.
,
26
, pp.
404
414
.
4.
Onik, G. M., 1995, “Prostate Cryoablation: A Reappraisal,” in Percutaneous Cryoablation, G. M. Onik, B. Rubinsky, G. Watson, and R. J. Ablin, eds., Quality Medical Publications, St. Louis, MO.
5.
Walder, H. A. D., 1971, “Experimental Cryosurgery,” in Cryogenics in Surgery, H. Van Leden and W. G. Cahan, eds., Medical Examination Publishing Co.
6.
Rabin
,
Y.
, and
Shitzer
,
A.
,
1996
, “
A New Cryosurgical Device For Controlled Freezing. Part 1: Setup and Validation Tests
,”
Cryobiology
,
33
, pp.
82
92
.
7.
Larson
,
T. R.
,
Robertson
,
D. W.
,
Corica
,
A.
, and
Bostwick
,
D. G.
,
2000
, “
In Vivo Interstitial Temperature Mapping of the Human Prostate During Cryosurgery With Correlation With Histopathological Outcomes
,”
Urology
,
55
, pp.
547
552
.
8.
Cooper
,
T. E.
, and
Trezek
,
G. J.
,
1970
, “
Analytical Prediction of the Temperature Field Emanating From Acryogenic Surgical Cannula
,”
Cryobiology
,
7
, pp.
79
93
.
9.
Rubinsky
,
B.
, and
Shitzer
,
A.
,
1976
, “
Analysis of a Stefan-Like Problem in a Biological Tissue Around a Cryosurgical Probe
,”
ASME J. Heat Transfer
,
98
, pp.
514
519
.
10.
Comini
,
G.
, and
Del Giudice
,
S.
,
1976
, “
Thermal Aspects of Cryosurgery
,”
ASME J. Heat Transfer
,
98
, pp.
543
549
.
11.
Keanini
,
R. G.
, and
Rubinsky
,
B.
,
1992
, “
Optimization of Multiprobe Cryosurgery
,”
ASME J. Heat Transfer
,
114
, pp.
796
801
.
12.
Weill
,
A.
,
Shitzer
,
A.
, and
Bar-Yoseph
,
P.
,
1993
, “
Finite Element Analysis of the Temperature Field Around Two Adjacent Cryo-Probes
,”
ASME J. Biomech. Eng.
,
115
, pp.
374
379
.
13.
Rabin
,
Y.
,
1998
, “
Uncertainty in Temperature Measurements During Cryosurgery
,”
Cryo-Lett.
,
19
, pp.
213
224
.
14.
Rabin, Y., 2003, “Cryoheater as a Means of Cryosurgery Control,” IMECE-41100, Proc. IMECE’03, Washington DC, 15–21 November 2003.
15.
Trezek, G. J., 1985, “Thermal Analysis for Cryosurgery,” in Heat Transfer in Medicine and Biology: Analysis and Applications, A. Shitzer and R. C. Eberhart eds., Plenum Publishing Corp., New York, pp. 239–259.
16.
Rubinsky
,
B.
,
2000
, “
Cryosurgery
,”
Annu. Rev. Biomed. Eng.
,
2
, pp.
157
187
.
17.
Lunardini
,
V. J.
,
1983
, “
Approximate Phase-Change Solutions For Insulated Buried Cylinders
,”
J. Heat Transfer
,
105
, pp.
25
33
.
18.
Sadegh
,
A. M.
,
Jiji
,
L. M.
, and
Weinbaum
,
S.
,
1987
, “
Boundary Integral Equation Technique With Application to Freezing a Round a Buried Pipe
,”
Int. J. Heat Mass Transfer
,
30
, pp.
223
232
.
19.
Negiz
,
A.
,
Hastaoglu
,
M. A.
, and
Heidemann
,
R. A.
,
1995
, “
Three-Dimensional Transient Heat Transfer From a Buried Pipe: Solidification of a Stationary Fluid
,”
Numer. Heat Transfer
,
28
, pp.
175
193
.
20.
Chayut, Y., and Shitzer, A., 1996, “Simulating the Effects of a Large Blood Vessel on the Temperature Field Around a Surface Cryoprobe,” ASME Advances in Heat and Mass Transfer in Biotechnology, L. J. Hayes and S. Clegg, eds, HTD-337, BED-34, pp. 21–22.
21.
Cooney, D. O., 1976, Biomedical Engineering Principles—An Introduction to Fluid, Heat and Mass Transport Processes, Marcel Dekker Inc., New York and Basel.
22.
Doebelin, E. O., 1966, Measurement Systems: Application and Design, McGraw-Hill Book Co., New York.
23.
Bonacina
,
C.
,
Comini
,
G.
,
Fasano
,
A.
, and
Primicerio
,
M.
,
1974
, “
On the Estimation of Thermophysical Properties in Nonlinear Heat-Conduction Problems
,”
Int. J. Heat Mass Transfer
,
17
, pp.
861
867
.
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