Dale R Fish scite author profile

Wingate

1985

We assessed accuracy and potential sources of error in goniometry by using a photographic reference standard. Forty-six physical therapy students measured elbow positions using plastic or steel goniometers following three protocols: ALIGN, in which the investigator's elbow was splinted and bony landmarks were prelabeled; ASSIGN, in which the elbow remained splinted but labels were removed; and PROM, in which raters measured full passive flexion of the elbow. F ratios of variances indicated that alignment of goniometer, identification of landmarks, and variations in manual force during PROM contributed to goniometric error and that accuracy of joint angle measurement by photography (s +/- 0.7-1.1 degrees) was greater than by standard goniometry (s +/- 2.4-3.4 degrees). Analysis of variance and post-hoc test results unexpectedly indicated that all but one goniometric mean differed statistically (p less than .05) from associated photographic means. Small systematic errors in alignment of goniometers and identification of reference landmarks may have accounted for these differences. The results indicate that relatively inexperienced raters should be able to use goniometers accurately to measure elbow position when given standardized methods to follow.

Influence of High Voltage Pulsed Direct Current on Edema Formation Following Impact Injury

Bettany

Mendel

1990

Edema results in pain and may lead to reduced functional mobility. High voltage pulsed direct current (HVPC) has recently been advocated for edema control. The purpose of our study was to determine the effect of HVPC on edema formation in frogs. Hind limbs of 20 anesthetized frogs were injured by dropping a 450-g weight onto the plantar aspects of the feet. One hind limb of each frog was randomly selected to receive continuous 120-Hz HVPC at voltages 10% lower than those needed to evoke muscle contraction. Four 30-minute treatments were administered at 1.5-hour intervals beginning 10 minutes after trauma. Limb volumes were measured by water displacement. An analysis of variance for repeated measures and a Newman-Keuls post hoc test were used to determine the significance of treatment effects. The HVPC significantly (p less than .01) reduced edema formation. We hypothesize that HVPC may also be effective in controlling edema formation after impact injuries in humans. [Bettany JA, Fish DR, Mendel FC: Influence of high voltage pulsed direct current on edema formation following impact injury.

Respiratory arrest: a complication of cerebellar ectopia in adults.

Journal of Neurology, Neurosurgery & Psychiatry

Howard

Wiles

et al. 1988

Effect of a Single 30-Minute Treatment of High Voltage Pulsed Current on Edema Formation in Frog Hind Limbs

Taylor

Mendel

et al. 1992

The purpose of this study was to investigate the effect of a single treatment of high voltage pulsed current (HVPC) on edema formation. Twenty-four frogs were anesthetized, and both hind limbs of each frog were traumatized by impact. Limb volumes were measured by water displacement immediately before and after trauma and at predetermined intervals for 24.0 hours posttrauma. One limb of each frog was randomly selected to receive 30 minutes of continuous, 120-pulse per second, cathodal HVPC at voltages 10% less than motor threshold levels. Data were analyzed by an analysis of variance for repeated measures. Sources of significant differences were determined by paired t tests (probability values determined by Bonferroni adjustment). A single 30-minute application of HVPC significantly curbed edema formation for between 4.0 and 7.5 hours following treatment (ie, volumes of treated limbs were significantly less than those of untreated limbs). These results suggest that regimens currently applied to humans (ie, one treatment per day or three times per week) may be insufficiently aggressive to provide sustained treatment effects.

Effects of Electrical Stimulation on Edema Formation in Different Strains of Rats

Thornton

Mendel

1998