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The Long Term Effects of Short-Wave Diathermy and Long-Duration Static Stretch on Hamstring FlexibilityGraham, Daniel Joseph 01 December 2004 (has links) (PDF)
Objective: To compare changes in hamstring flexibility from treatments of pulsed short- wave diathermy and prolonged stretch versus sham diathermy and prolonged stretch and control and to observe how long those changes last.
Background: Heat and stretch techniques have been touted for years. To date, the effect of short-wave diathermy and hamstring stretching has not been thoroughly studied. Because diathermy heats a large area and penetrates deep into the muscle, use of this device prior to or during hamstring stretching may increase flexibility and these gains may last longer.
Study Design: A randomized, counterbalanced 3x2x6 repeated measures design. The 3 independent variables were day, pretest/posttest, and treatment mode. Treatment mode had 3 levels: diathermy and stretch, sham diathermy and stretch, and control. The dependent variable was the change in knee extension range of motion (ROM).
Methods and Measures: Thirty college-age students with tight hamstrings (inability to achieve >160° knee extension at 90° hip flexion) participated. Subjects were assigned to 1 of 3 groups, (diathermy and stretch; sham diathermy and stretch; control). Range of motion was recorded before and after each treatment every other day for 2 weeks. Additional ROM measures were taken on days 15, 22, 29, and 36. A straight-leg raise stretch was performed using a mechanical apparatus. Subjects in the diathermy and stretch group received 10 minutes of diathermy (distal hamstrings), 5 minutes of diathermy and stretch, followed by 5 minutes of stretching only. Subjects in the sham diathermy and stretch group followed the same protocol, except the diathermy unit was turned off. Subjects in the control group lay on the table for 20 minutes. Data were analyzed using an ANOVA, an ANCOVA, and post hoc t-tests.
Results: Least Squares (LS) Mean (± Pooled SE) increases in knee extension after 6 treatments were: 11.3 ± 1.2° for the diathermy and stretch group; 10.0 ± 1.2° for the sham diathermy and stretch group; and 3.2 ± 1.2° for the control group. At Day 15, 3 days after the last treatment, the diathermy and stretch group lost 6.9 ± 0.8°; the sham diathermy and stretch group lost 6.6 ± 0.8°; and the control group changed 1.6 ± 0.8°. At Day 22 the diathermy and stretch group had lost 7.4 ± 0.8°; the sham diathermy and stretch group lost 6.8 ± 0.8°; and the control group changed 1.7 ± 0.8° from the last treatment. At Day 29 the diathermy and stretch group had lost 8.2 ± 0.9°; the sham diathermy and stretch group lost 7.1 ± 0.9°; and the control group changed 1.7 ± 0.8° from the last treatment. At Day 36 the diathermy and stretch group had lost 8.3 ± 0.8°; the sham diathermy and stretch group lost 7.4 ± 0.8°; and the control group changed 2.1 ± 0.8° from the last treatment.
Conclusion: These results indicate that hamstring flexibility can be improved when long-duration or prolonged stretching is used and that those improvements will slowly diminish over several weeks. Clinicians should consider the use of long-duration stretch to help patients with tight hamstrings increase flexibility and maintain those gains over time.
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Peristaltic Pulse Dynamic Compression of the Lower Extremity Enhances FlexibilitySands, William A., Murray, Melonie B., Murray, Steven R., McNeal, Jeni R., Mizuguchi, Satoshi, Sato, Kimitake, Stone, Michael H. 01 April 2014 (has links)
This study investigated the effects of peristaltic pulse dynamic compression (PPDC) on range-of-motion (ROM) changes in forward splits. Serious stretching usually involves discomfort and large time investments. Tissue structural changes and stretch tolerance have heretofore been considered the primary mechanisms of enhanced ROM. The PPDC treatment was computer controlled. Circumferential and segmented inflation pressures were induced by feet to hip leggings. Nine subjects, experienced in stretching and a forward split position, volunteered. The subjects were familiarized with the protocol and randomly assigned to an initial condition: experimental (PPDC), or control (CONT). The study involved a crossover design. Second conditions were tested within 1–5 days. All tests were 2 trials of right and left forward splits. Split flexibility was assessed by measuring the height of the anterior superior iliac spine of the rear leg from the floor. Pelvic posture was controlled by rear leg position. The PPDC treatment was 15 minutes of seated PPDC. The control condition was the same except that leggings were not inflated. Pressures of 5 cells in the leggings were set at factory defaults, 70 mm Hg sequentially. Difference score results indicated statistically significant (p ≤ 0.05) differences by condition and the condition by leg interaction. The rapid acute changes in ROM (PPDC: right 25.3%, left 33.3%; CONT: right 12.2%, left 1.0%) support the premise that changes in ROM were dependent on mechanisms other than tissue structural changes and/or stretch tolerance. PPDC provides a means of rapidly enhancing acute ROM requiring less discomfort and time.
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