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Abstract

BACKGROUND:

Electrical stimulation is shown to be effective for the amelioration of paralysis. The stimulation pattern can have a direct relation to injected charge in the stimulated area resulting in a wider area stimulation and consequently better recovery.

OBJECTIVE:

In this study, we investigated the effect of two electrical stimulation waveforms, rectangular and exponentially climbing. Three parameters of current, voltage, and knee extension torque of the 2 waveforms were recorded and used for the comparison of the two waveforms.

METHODS:

Fifteen male and 15 female able-bodied subjects (age: 25.0± 3.2) were recruited. Electrical stimulation was applied to right quadriceps muscles. At the maximum tolerable intensity, the 3 parameters were recorded for each of the 2 waveforms. Using the recorded knee extension torques, the adjusted maximum electrically induced contraction to voluntary torques in percent (%MEIC) of the two waveforms were calculated. Together with the other two parameters, current and voltage, the 2 waveforms were compared.

RESULTS:

The %MEIC and maximum voltage were significantly higher with the exponentially climbing waveform than with the rectangular waveform(%MEIC: p < 0.05, max voltage: p < 0.01). The maximum current did not differ significantly between conditions.

CONCLUSION:

These results indicate that an exponentially climbing waveform may induce stronger torque than a rectangular waveform and might thus be useful when applying NMES in clinical situations.

Keywords

Neuromuscular electrical stimulation electrical stimulation waveform knee extension torque

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Effect of rectangular and exponentially climbing waveforms on knee extension torque during neuromuscular electrical stimulation

Abstract

BACKGROUND:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSION:

Keywords

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References