Clifton Frilot scite author profile

Exercises for the ankle are often used to improve sport performance through balance and stability or to prevent or recover from ankle injury. Ankle training programs often include exercises for the primary muscle of the lateral ankle, the peroneus longus (PL). However, many exercises for the PL are non-weight bearing and unidirectional. However, data from biomechanical studies show that peak activity of the PL occurs neither in non-weight-bearing nor during uniplanar movements. This lack of congruency may limit the effectiveness of PL training. Exercises more consistent with the biomechanical function of the PL may increase the efficacy of ankle training. This study examined and compared the electromyographic (EMG) activity of the PL during 2 exercises that specifically address the known biomechanical function of the PL and a traditional non-weight-bearing unidirectional PL exercise. Twenty healthy college-aged men and women (age 24.8 +/- 2.7 years) without history of ankle injury were examined in a single-session repeated measures design. The average root means square (RMS) values of the PL during each of the 3 exercises were measured and compared to assess for differences in magnitude of muscular activity. The RMS activity of the PL was significantly greater (p < 0.05) in each of the biomechanically correct exercises when compared with the conventional exercise. However, no significant difference was noted in EMG activity between the 2 biomechanical exercises. This study provides evidence for increased activity from the PL during 2 exercises that more accurately reflect its biomechanical function. Use of these exercises when training the PL for sports performance or rehabilitation may increase the effectiveness of ankle training programs that include PL activity.

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Nonlinear response of the immune system to power-frequency magnetic fields

Marino¹,

Wolcott

Chervenak

et al. 2000

American Journal of Physiology-Regulatory, Integrative and Comp

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Studies of the effects of power-frequency electromagnetic fields (EMFs) on the immune and other body systems produced positive and negative results, and this pattern was usually interpreted to indicate the absence of real effects. However, if the biological effects of EMFs were governed by nonlinear laws, deterministic responses to fields could occur that were both real and inconsistent, thereby leading to both types of results. The hypothesis of real inconsistent effects due to EMFs was tested by exposing mice to 1 G, 60 Hz for 1-105 days and observing the effect on 20 immune parameters, using flow cytometry and functional assays. The data were evaluated by means of a novel statistical procedure that avoided averaging away oppositely directed changes in different animals, which we perceived to be the problem in some of the earlier EMF studies. The reliability of the procedure was shown using appropriate controls. In three independent experiments involving exposure for 21 or more days, the field altered lymphoid phenotype even though the changes in individual immune parameters were inconsistent. When the data were evaluated using traditional linear statistical methods, no significant difference in any immune parameter was found. We were able to mimic the results by sampling from known chaotic systems, suggesting that deterministic chaos could explain the effect of fields on the immune system. We conclude that exposure to power-frequency fields produced changes in the immune system that were both real and inconsistent.

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Clifton Frilot

Evidence of a nonlinear human magnetic sense

Effect of low-frequency magnetic fields on brain electrical activity in human subjects

Electromagnetic Hypersensitivity: Evidence for a Novel Neurological Syndrome

Facilitating Activation of the Peroneus Longus: Electromyographic Analysis of Exercises Consistent With Biomechanical Function

Nonlinear response of the immune system to power-frequency magnetic fields

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