OBJECTIVE: To compare tissue temperature rise and decay after 20-minute diathermy and ultrasound treatments. DESIGN AND SETTING: We inserted 3 26-gauge thermistor microprobes into the medial aspect of the anesthetized triceps surae muscle at a depth of 3 cm and spaced 5 cm apart. Eight subjects received the diathermy treatment first, followed by the ultrasound treatment. This sequence was reversed for the remaining 8 subjects. The diathermy was applied at a frequency of 27.12 MHz at the following settings: 800 bursts per second, 400-microsecond burst duration, 850-microsecond interburst interval, peak root mean square amplitude of 150 W per burst, and an average root mean square output of 48 W per burst. The ultrasound was delivered at a frequency of 1 MHz and an intensity of 1.5 W/cm(2) in the continuous mode for 20 minutes over an area of 40 times the effective radiating area. The study was performed in a ventilated research laboratory. SUBJECTS: Sixteen (11 men, 5 women) healthy subjects (mean age = 23.56 +/- 4.73 years) volunteered to participate in this study. MEASUREMENTS: We recorded baseline, final, and decay temperatures for each of the 3 sites. RESULTS: The average temperature increases over baseline temperature after pulsed short-wave diathermy were 3.02 degrees C +/- 1.02 degrees C in site 1, 4.58 degrees C +/- 0.87 degrees C in site 2, and 3.28 degrees C +/- 1.64 degrees C in site 3. The average temperature increases over baseline temperature after ultrasound were only 0.17 degrees C +/- 0.40 degrees C, 0.09 degrees C +/- 0.56 degrees C, and -0.43 degrees C +/- 0.41 degrees C in sites 1, 2, and 3, respectively. The temperature dropped only 1 degrees C in 7.65 +/- 4.96 minutes after pulsed short-wave diathermy. CONCLUSIONS: We conclude that pulsed short-wave diathermy was more effective than 1-MHz ultrasound in heating a large muscle mass and resulted in the muscles' retaining heat longer.
OBJECTIVE: To compare tissue temperature rise and decay after 20-minute diathermy and ultrasound treatments. DESIGN AND SETTING: We inserted 3 26-gauge thermistor microprobes into the medial aspect of the anesthetized triceps surae muscle at a depth of 3 cm and spaced 5 cm apart. Eight subjects received the diathermy treatment first, followed by the ultrasound treatment. This sequence was reversed for the remaining 8 subjects. The diathermy was applied at a frequency of 27.12 MHz at the following settings: 800 bursts per second, 400-microsecond burst duration, 850-microsecond interburst interval, peak root mean square amplitude of 150 W per burst, and an average root mean square output of 48 W per burst. The ultrasound was delivered at a frequency of 1 MHz and an intensity of 1.5 W/cm(2) in the continuous mode for 20 minutes over an area of 40 times the effective radiating area. The study was performed in a ventilated research laboratory. SUBJECTS: Sixteen (11 men, 5 women) healthy subjects (mean age = 23.56 +/- 4.73 years) volunteered to participate in this study. MEASUREMENTS: We recorded baseline, final, and decay temperatures for each of the 3 sites. RESULTS: The average temperature increases over baseline temperature after pulsed short-wave diathermy were 3.02 degrees C +/- 1.02 degrees C in site 1, 4.58 degrees C +/- 0.87 degrees C in site 2, and 3.28 degrees C +/- 1.64 degrees C in site 3. The average temperature increases over baseline temperature after ultrasound were only 0.17 degrees C +/- 0.40 degrees C, 0.09 degrees C +/- 0.56 degrees C, and -0.43 degrees C +/- 0.41 degrees C in sites 1, 2, and 3, respectively. The temperature dropped only 1 degrees C in 7.65 +/- 4.96 minutes after pulsed short-wave diathermy. CONCLUSIONS: We conclude that pulsed short-wave diathermy was more effective than 1-MHz ultrasound in heating a large muscle mass and resulted in the muscles' retaining heat longer.
Authors: Lisa S Jutte; Kenneth L Knight; Blaine C Long; Jeremy R Hawkins; Shane S Schulthies; Ethan B Dalley Journal: J Athl Train Date: 2005 Jul-Sep Impact factor: 2.860
Authors: Michale G Miller; Janae R Longoria; Christopher C Cheatham; Robert J Baker; Timothy J Michael Journal: J Sports Sci Med Date: 2008-06-01 Impact factor: 2.988
Authors: John P Vardiman; Nicole Moodie; Jacob A Siedlik; Rebecca A Kudrna; Zachary Graham; Philip Gallagher Journal: J Athl Train Date: 2015-04-06 Impact factor: 2.860
Authors: Chad Touchberry; Tung Le; Scott Richmond; Mike Prewitt; David Beck; David Carr; Phil Vardiman; Philip Gallagher Journal: Eur J Appl Physiol Date: 2007-10-18 Impact factor: 3.078