Synthetic and Bio-Artificial Tactile Sensing: A Review

Lucarotti, Chiara; Oddo, Calogero Maria; Vitiello, Nicola; Carrozza, Maria Chiara

doi:10.3390/s130201435

Cited by 134 publications

(97 citation statements)

References 105 publications

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“…The Physarum sensors and information pathways presented could make a feasible complement to biohybrid sensors incorporating live cells as parts of transduction systems [65,24]. Typically, living substrates integrated into biohybrid systems rely on external bandwidth, such as microfabricated vascular networks [55], to receive nutrients and remove metabolites [46]. The slime mold nervous system does not require any auxiliary life support system, and can reside on virtually any surface for days or weeks, depending on the humidity.…”

Section: Discussionmentioning

confidence: 99%

A Would-Be Nervous System Made from a Slime Mold

Adamatzky

2015

Artificial Life

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The slime mold Physarum polycephalum is a huge single cell that has proved to be a fruitful material for designing novel computing architectures. The slime mold is capable of sensing tactile, chemical, and optical stimuli and converting them to characteristic patterns of its electrical potential oscillations. The electrical responses to stimuli may propagate along protoplasmic tubes for distances exceeding tens of centimeters, as impulses in neural pathways do. A slime mold makes decisions about its propagation direction based on information fusion from thousands of spatially extended protoplasmic loci, similarly to a neuron collecting information from its dendritic tree. The analogy is distant yet inspiring. We speculate on whether alternative-would-be-nervous systems can be developed and practically implemented from the slime mold. We uncover analogies between the slime mold and neurons, and demonstrate that the slime mold can play the roles of primitive mechanoreceptors, photoreceptors, and chemoreceptors; we also show how the Physarum neural pathways develop. The results constituted the first step towards experimental laboratory studies of nervous system implementation in slime molds.

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Section: Discussionmentioning

confidence: 99%

A Would-Be Nervous System Made from a Slime Mold

Adamatzky

2015

Artificial Life

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“…In parallel to the bio-hybrid route for actuation, whole cells have been also proposed as sensing elements Lucarotti et al 2013;Adamatzki 2013). In this case, such devices largely exceed the nanoscale dimensions.…”

Section: Nanotechnology For Sensingmentioning

confidence: 99%

Nanotechnology in biorobotics: opportunities and challenges

Ricotti

Menciassi

2015

J Nanopart Res

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Nanotechnology recently opened a series of unexpected technological opportunities that drove the emergence of novel scientific and technological fields, which have the potential to dramatically change the lives of millions of citizens. Some of these opportunities have been already caught by researchers working in the different fields related to biorobotics, while other exciting possibilities still lie on the horizon. This article highlights how nanotechnology applications recently impacted the development of advanced solutions for actuation and sensing and the achievement of microrobots, nanorobots, and non-conventional larger robotic systems. The open challenges are described, together with the most promising research avenues involving nanotechnology

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“…In order to replicate the capabilities of human skin, a diversity of sensing principles have been adopted in the development of the single sensing elements composing an artificial skin [4]. These, used alone or in combination with others, allowed the development of artificial skins capable of distinguishing between different phenomena, such as pressure, vibration, and temperature.…”

Section: Introductionmentioning

confidence: 99%

A Deformable Smart Skin for Continuous Sensing Based on Electrical Impedance Tomography

Visentin

Fiorini

Suzuki

2016

Sensors

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In this paper, we present a low-cost, adaptable, and flexible pressure sensor that can be applied as a smart skin over both stiff and deformable media. The sensor can be easily adapted for use in applications related to the fields of robotics, rehabilitation, or costumer electronic devices. In order to remove most of the stiff components that block the flexibility of the sensor, we based the sensing capability on the use of a tomographic technique known as Electrical Impedance Tomography. The technique allows the internal structure of the domain under study to be inferred by reconstructing its conductivity map. By applying the technique to a material that changes its resistivity according to applied forces, it is possible to identify these changes and then localise the area where the force was applied. We tested the system when applied to flat and curved surfaces. For all configurations, we evaluate the artificial skin capabilities to detect forces applied over a single point, over multiple points, and changes in the underlying geometry. The results are all promising, and open the way for the application of such sensors in different robotic contexts where deformability is the key point.

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Synthetic and Bio-Artificial Tactile Sensing: A Review

Cited by 134 publications

References 105 publications

A Would-Be Nervous System Made from a Slime Mold

A Would-Be Nervous System Made from a Slime Mold

Nanotechnology in biorobotics: opportunities and challenges

A Deformable Smart Skin for Continuous Sensing Based on Electrical Impedance Tomography

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