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Items: 1 to 20 of 259

1.

Interstitial helical coil microwave antenna for experimental brain hyperthermia.

Satoh T, Seilhan TM, Stauffer PR, Sneed PK, Fike JR.

Neurosurgery. 1988 Nov;23(5):564-9.

PMID:
3059216
2.

Implantable helical coil microwave antenna for interstitial hyperthermia.

Satoh T, Stauffer PR.

Int J Hyperthermia. 1988 Sep-Oct;4(5):497-512.

PMID:
3392424
3.

[Characterization of helical coil microwave antenna for interstitial hyperthermia].

Satoh T, Stauffer PR, Fike JR.

Gan No Rinsho. 1988 Sep;34(11):1544-9. Japanese.

PMID:
3184458
4.

Thermal distribution studies of helical coil microwave antennas for interstitial hyperthermia.

Satoh T, Stauffer PR, Fike JR.

Int J Radiat Oncol Biol Phys. 1988 Nov;15(5):1209-18.

PMID:
3182353
5.

Experimental brain hyperthermia: techniques for heat delivery and thermometry.

Ryan TP, Hoopes PJ, Taylor JH, Strohbehn JW, Roberts DW, Douple EB, Coughlin CT.

Int J Radiat Oncol Biol Phys. 1991 Apr;20(4):739-50.

PMID:
2004950
7.

Interstitial microwave hyperthermia in a canine brain model.

Sneed PK, Matsumoto K, Stauffer PR, Fike JR, Smith V, Gutin PH.

Int J Radiat Oncol Biol Phys. 1986 Oct;12(10):1887-97.

PMID:
3759542
8.

Prediction of heating patterns of a microwave interstitial antenna array at various insertion depths.

Zhang Y, Joines WT, Oleson JR.

Int J Hyperthermia. 1991 Jan-Feb;7(1):197-207.

PMID:
2051073
9.
10.

Hyperthermia for brain tumors: improved delivery with a new cooling system.

Moriyama E, Matsumi N, Shiraishi T, Tamiya T, Satoh T, Matsumoto K, Furuta T, Nishimoto A.

Neurosurgery. 1988 Aug;23(2):189-95.

PMID:
3185878
11.

Dielectric-loaded coaxial-slot antenna for interstitial microwave hyperthermia: longitudinal control of heating patterns.

Hamada L, Saito K, Yoshimura H, Ito K.

Int J Hyperthermia. 2000 May-Jun;16(3):219-29.

PMID:
10830585
12.

Interstitial microwave-induced hyperthermia and iridium brachytherapy for the treatment of obstructing biliary carcinomas.

Coughlin CT, Wong TZ, Ryan TP, Jones EL, Crichlow RW, Spiegel PK, Jeffery R.

Int J Hyperthermia. 1992 Mar-Apr;8(2):157-71.

PMID:
1573307
13.

Heating patterns generated by phase modulation of a hexagonal array of interstitial antennas.

Zhang Y, Joines WT, Oleson JR.

IEEE Trans Biomed Eng. 1991 Jan;38(1):92-7.

PMID:
2026438
14.

SAR distributions in interstitial microwave antenna arrays with a single dipole displacement.

Clibbon KL, McCowen A, Hand JW.

IEEE Trans Biomed Eng. 1993 Sep;40(9):925-32.

PMID:
8288284
15.

[Fundamental study of differential hypothermia treatment of brain tumor using an interstitial microwave antenna].

Moriyama E, Matsumi N, Shiraishi T, Tamiya T, Sato T, Matsumoto K, Furuta T, Nishimoto A.

No Shinkei Geka. 1987 Dec;15(12):1291-7. Japanese.

PMID:
3448498
16.

Investigation into the thermal distribution of microwave helical antennas designed for the treatment of Barrett's oesophagus.

Reeves J, Birch M, Munro K, Collier R.

Phys Med Biol. 2002 Oct 7;47(19):3557-64.

PMID:
12408482
17.

The effect of insertion depth on the theoretical SAR patterns of 915 MHz dipole antenna arrays for hyperthermia.

James BJ, Strohbehn JW, Mechling JA, Trembly BS.

Int J Hyperthermia. 1989 Nov-Dec;5(6):733-47.

PMID:
2592787
18.

A coaxial microwave applicator for transurethral hyperthermia of the prostate.

Wong TZ, Jonsson E, Hoopes PJ, Trembly BS, Heaney JA, Douple EB, Coughlin CT.

Prostate. 1993;22(2):125-38.

PMID:
7681205
19.

[The characterization of semirigid coaxial antennae for interstitial and endocavitary microwave hyperthermia].

Erb J, Klautke G, Seegenschmiedt HM, Engelbrecht R, Schaller G, Sauer R.

Strahlenther Onkol. 1994 Nov;170(11):654-64. German.

PMID:
7974181
20.

Temperature mapping in the canine prostate during transurethrally-applied local microwave hyperthermia.

Roehrborn CG, Krongrad A, McConnell JD.

Prostate. 1992;20(2):97-104.

PMID:
1372431

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