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Area of Science:

  • Biomedical Engineering
  • Neuroscience
  • Medical Technology

Background:

  • Neuromodulation offers effective treatments for various challenging medical conditions.
  • Progress requires deeper understanding of neural control mechanisms and advanced modulation technologies.

Purpose of the Study:

  • To review recent research on neuromodulation devices.
  • To highlight devices enabling precise, programmable neural function modulation.
  • To focus on advancements in multimodal, miniaturized, and biocompatible designs.

Main Methods:

  • Review of current scientific literature on neuromodulation devices.
  • Emphasis on technologies with multimodal operation and miniaturized dimensions.
  • Discussion of biocompatible designs, advanced neural interfaces, and wireless power.

Main Results:

  • Recent research focuses on devices with multimodal operation and miniaturized dimensions.
  • Advancements include biocompatible designs, sophisticated neural interfaces, and battery-free wireless capabilities.
  • Emerging technologies incorporate closed-loop strategies and bioresorbable materials.

Conclusions:

  • Future neuromodulation systems will integrate recording and modulation capabilities.
  • Programmable, wireless, and biocompatible devices are key to future therapies.
  • Closed-loop and bioresorbable neuromodulation systems are becoming increasingly feasible.