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Related Experiment Video

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Neuronavigated Focalized Transcranial Direct Current Stimulation Administered During Functional Magnetic Resonance Imaging
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Printable devices for neurotechnology.

Rita Matta1, David Moreau1, Rodney O'Connor1,2

  • 1Mines Saint-Etienne, Centre CMP, Departement BEL, Gardanne, France.

Frontiers in Neuroscience
|March 5, 2024
PubMed
Summary
This summary is machine-generated.

Printable electronics offer a cost-effective way to create advanced neurotechnology for brain research and treatment. This review covers printing methods, materials, and applications, highlighting future potential and challenges.

Keywords:
microelectrode arraysneuroprobesneurotechnologyprintable devicesprintable electronics

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Area of Science:

  • Neurotechnology
  • Materials Science
  • Biomedical Engineering

Background:

  • Printable electronics are emerging for neurotechnology, offering rapid prototyping, scalability, and cost-effectiveness.
  • These devices are crucial for applications in neurobiology, including neuronal signal recording and controlled drug delivery.

Purpose of the Study:

  • To review printing techniques, materials, and applications for printable electronic devices in neurotechnology.
  • To highlight the advantages and challenges associated with these emerging technologies.

Main Methods:

  • Overview of various printing techniques such as inkjet, screen printing, flexographic printing, and 3D printing.
  • Discussion of material selection criteria including biocompatibility, flexibility, electrical properties, and durability.
  • Exploration of applications including neuroprobes, electrocorticography (ECoG) arrays, and microelectrode arrays.

Main Results:

  • Printable devices offer flexibility, biocompatibility, and scalability for cost-effective preclinical research.
  • Key materials include conductive nanoparticles, conducting polymers, and dielectric polymers like polyimide and polycaprolactone.
  • Various printing methods present unique advantages and challenges in precision, resolution, and material compatibility.

Conclusions:

  • Printable electronics hold significant potential for advancing brain research and neurological disorder treatments.
  • Overcoming challenges in biocompatibility, precision, electrical performance, long-term stability, and regulatory approval is crucial for clinical translation.
  • Continued development in printable electronics will drive innovation in neurotechnology.