Andrea S. Lowe scite author profile

Rodent models of transcranial magnetic stimulation (TMS) play a crucial role in aiding the understanding of the cellular and molecular mechanisms underlying TMS induced plasticity. Rodent-specific TMS have previously been used to deliver focal stimulation at the cost of stimulus intensity (12 mT). Here we describe two novel TMS coils designed to deliver repetitive TMS (rTMS) at greater stimulation intensities whilst maintaining spatial resolution. Two circular coils (8 mm outer diameter) were constructed with either an air or pure iron-core. Peak magnetic field strength for the air and iron-cores were 90 and 120 mT, respectively, with the iron-core coil exhibiting less focality. Coil temperature and magnetic field stability for the two coils undergoing rTMS, were similar at 1 Hz but varied at 10 Hz. Finite element modeling of 10 Hz rTMS with the iron-core in a simplified rat brain model suggests a peak electric field of 85 and 12.7 V/m, within the skull and the brain, respectively. Delivering 10 Hz rTMS to the motor cortex of anaesthetized rats with the iron-core coil significantly increased motor evoked potential amplitudes immediately after stimulation (n = 4). Our results suggest these novel coils generate modest magnetic and electric fields, capable of altering cortical excitability and provide an alternative method to investigate the mechanisms underlying rTMS-induced plasticity in an experimental setting.

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The effect of high‐ and low‐frequency transcutaneous electrical nerve stimulation upon cutaneous blood flow and skin temperature in healthy subjects

Cramp

Gilsenan

Lowe

et al. 2000

Clinical Physiology

104

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The reported non-analgesic effects of transcutaneous electrical nerve stimulation (TENS) include alterations to the local circulation; however, research in this area has produced equivocal findings. In the present study, the effect of low- (4 Hz) and high-frequency (110 Hz) TENS on forearm skin blood perfusion was assessed using laser Doppler flowmetry. The effect on skin temperature was also assessed using a skin thermistor. Thirty healthy human volunteers were recruited and randomly assigned to a control or one of the two treatment groups. TENS was applied to the skin overlying the median nerve under double-blind conditions for 15 min. Blood flow and skin temperature readings were recorded pre-TENS, during TENS application and continued for 15 min post-TENS application. Analysis of results showed significant increases in blood perfusion during the treatment period in the low-frequency group when compared to the other two groups (P = 0.0106; ANOVA). No significant changes in skin temperature were observed. The results of this study demonstrate that low-frequency TENS produces a local increase in cutaneous blood flow.

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Effect of low-intensity laser irradiation (660 nm) on a radiation-impaired wound-healing model in murine skin

et al. 2000

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Transcutaneous electric nerve stimulation: The effect of intensity on local and distal cutaneous blood flow and skin temperature in healthy subjects

Cramp

McCullough

Lowe

et al. 2002

Archives of Physical Medicine and Rehabilitation

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Transcutaneous electrical nerve stimulation: Effect on peripheral nerve conduction, mechanical pain threshold, and tactile threshold in humans

Walsh

Lowe²,

McCormack

et al. 1998

Archives of Physical Medicine and Rehabilitation

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Andrea S. Lowe

Construction and Evaluation of Rodent-Specific rTMS Coils

The effect of high‐ and low‐frequency transcutaneous electrical nerve stimulation upon cutaneous blood flow and skin temperature in healthy subjects

Effect of low-intensity laser irradiation (660 nm) on a radiation-impaired wound-healing model in murine skin

Transcutaneous electric nerve stimulation: The effect of intensity on local and distal cutaneous blood flow and skin temperature in healthy subjects

Transcutaneous electrical nerve stimulation: Effect on peripheral nerve conduction, mechanical pain threshold, and tactile threshold in humans

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