Electrotactile stimulation on the tongue: Intensity perception, discrimination, and cross-modality estimation

Lozano, Cecil; Kaczmarek, K.A.; Santello, Marco

doi:10.1080/08990220903158797

Cited by 35 publications

(31 citation statements)

References 49 publications

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“…For example, guidance of a surgical tool manipulation has been demonstrated using only TDU-based feedback [94], and tactile feedback from robots to assist spinal cord injuries has been proposed [95], along with tactile feedback of seated pressure, to prevent pressure sores [96] and to gain greater awareness of ankle joint rotation in a fatigued state [97]. The TDU as a platform technology allows virtually any kind of information to be presented to the tongue, subject to the human limits of electrotactile perception on the tongue, which are just beginning to be explored [98]. …”

Section: Selected Applicationsmentioning

confidence: 99%

The tongue display unit (TDU) for electrotactile spatiotemporal pattern presentation

Kaczmarek

2011

Scientia Iranica

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The Tongue Display Unit (TDU) is a 144-channel programmable pulse generator that delivers dc-balanced voltage pulses suitable for electrotactile (electrocutaneous) stimulation of the anterior-dorsal tongue, through a matrix of surface electrodes. This article reviews the theory of operation and a design overview of the TDU, as well as selected applications. These include sensory substitution, tactile information display and neurorehabilitation via induced neuroplasticity.

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Section: Selected Applicationsmentioning

confidence: 99%

The tongue display unit (TDU) for electrotactile spatiotemporal pattern presentation

Kaczmarek

2011

Scientia Iranica

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“…Previous studies have been small (averaging eight participants each), and mostly centered on mapping the sensitivity of the tongue without analyzing electrotactile two-point discrimination ability (Lozano et al, 2009; Tyler et al, 2009; Wilson et al, 2012). These studies indicate that anterior-medial tongue regions have lower thresholds for electrotactile stimulation relative to posterior regions and sensitivity to electrotactile stimulation varies widely between individuals.…”

Section: Introductionmentioning

confidence: 99%

Perceived Intensity and Discrimination Ability for Lingual Electrotactile Stimulation Depends on Location and Orientation of Electrodes

Moritz

Turk

Williams

et al. 2017

Front. Hum. Neurosci.

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Malfunctioning sensory systems can severely impact quality of life and repair is not always possible. One solution, called sensory substitution, is to use another sensory system to bring lost information to the brain. This approach often involves the use of bioengineered devices that electrically stimulate somatosensory fibers. Interestingly, the tongue is an ideal location for electrotactile stimulation due to its dense innervation, moisture, and protected environment. Success with transmitting visual and vestibular information through the tongue indicates promise for future applications. However, sensitivity and discrimination ability varies between individuals and across the tongue surface complicating efforts to produce reliable and consistent sensations. The goals of the present study were to investigate these differences more precisely to better understand the mechanosensory innervation of the tongue so that future electrotactile devices can be designed more effectively. Specifically, we tested whether stimulation of certain regions of the tongue consistently result in better perception, whether the spacing of stimulating electrodes affects perceived intensity, and whether the orientation of electrodes affects perceived intensity and discrimination. To test these hypotheses, we built a custom tongue stimulation device, recruited 25 participants, and collected perceived intensity and discrimination data. We then subjected the data to thorough statistical analyses. Consistent with previous studies, we found that stimulation of the anterior medial tongue region was perceived as more intense than stimulation of lateral and posterior regions. This region also had the best discrimination ability for electrodes. Dividing the stimulated tongue area into 16 distinct regions allowed us to compare perception ability between anterior and posterior regions, medial and lateral regions, and the left and right sides of the tongue. Stimulation of the most anterior and medial tongue resulted in the highest perceived intensity and the best discrimination ability. Most individuals were able to perceive and discriminate electrotactile stimulation better on one side of the tongue, and orientation of stimulating electrodes affected perception. In conclusion, the present studies reveal new information about the somatosensory innervation of the tongue and will assist the design of future electrotactile tongue stimulation devices that will help provide sensory information to people with damaged sensory systems.

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“…Previously, our group and others have shown that the tongue can be used as an effective interface for sending signals to the central nervous system (Chebat et al 2007; Bach-y-Rita and Kercel 2003; Sampaio et al 2001; Bach-y-Rita et al 1998). Compared to the skin, the tongue provides an inviting target for electrical neurostimulation due to the high electrolyte content of saliva, allowing for low-impedance electrical input, and the high density of sensory receptors permitting reasonably high throughput of incoming signals while preserving a relatively large dynamic range (Lozano et al 2009). Additionally, because tongue neurostimulation is non-invasive, it avoids a major drawback of other commonly-used types of electrical neurostimulation such as vagal nerve and deep brain stimulation while exhibiting less non-specific activation than other non-invasive modalities such as transcranial magnetic or direct current stimulation.…”

Section: Introductionmentioning

confidence: 99%

Sustained cortical and subcortical neuromodulation induced by electrical tongue stimulation

Wildenberg

Tyler

Danilov

et al. 2010

Brain Imaging and Behavior

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This pilot study aimed to show that information-free stimulation of the tongue can improve behavioral measures and induce sustained neuromodulation of the balance-processing network in individuals with balance dysfunction. Twelve balance-impaired subjects received one week of cranial nerve non-invasive neuromodulation (CN-NINM). Before and after the week of stimulation, postural sway and fMRI activation were measured to monitor susceptibility to optic flow. Nine normal controls also underwent the postural sway and fMRI tests but did not receive CN-NINM. Results showed that before CN-NINM balance-impaired subjects swayed more than normal controls as expected (p≤0.05), and that overall sway and susceptibility to optic flow decreased after CN-NINM (p≤0.005 & p≤0.05). fMRI showed upregulation of visual sensitivity to optic flow in balance-impaired subjects that decreased after CN-NINM. A region of interest analysis indicated that CN-NINM may induce neuromodulation by increasing activity within the dorsal pons (p≤0.01).

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Electrotactile stimulation on the tongue: Intensity perception, discrimination, and cross-modality estimation

Cited by 35 publications

References 49 publications

The tongue display unit (TDU) for electrotactile spatiotemporal pattern presentation

The tongue display unit (TDU) for electrotactile spatiotemporal pattern presentation

Perceived Intensity and Discrimination Ability for Lingual Electrotactile Stimulation Depends on Location and Orientation of Electrodes

Sustained cortical and subcortical neuromodulation induced by electrical tongue stimulation

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