Abstract
Bidirectional brain-machine interfaces (BMIs) establish a two-way direct communication link between the brain and the external world. A decoder translates recorded neural activity into motor commands and an encoder delivers sensory information collected from the environment directly to the brain creating a closed-loop system. These two modules are typically integrated in bulky external devices. However, the clinical support of patients with severe motor and sensory deficits requires compact, low-power, and fully implantable systems that can decode neural signals to control external devices. As a first step toward this goal, we developed a modular bidirectional BMI setup that uses a compact neuromorphic processor as a decoder. On this chip we implemented a network of spiking neurons built using its ultra-low-power mixed-signal analog/digital circuits. On-chip on-line spike-timing-dependent plasticity synapse circuits enabled the network to learn to decode neural signals recorded from the brain into motor outputs controlling the movements of an external device. The modularity of the BMI allowed us to tune the individual components of the setup without modifying the whole system. In this paper, we present the features of this modular BMI and describe how we configured the network of spiking neuron circuits to implement the decoder and to coordinate it with the encoder in an experimental BMI paradigm that connects bidirectionally the brain of an anesthetized rat with an external object. We show that the chip learned the decoding task correctly, allowing the interfaced brain to control the object's trajectories robustly. Based on our demonstration, we propose that neuromorphic technology is mature enough for the development of BMI modules that are sufficiently low-power and compact, while being highly computationally powerful and adaptive.
Highlights
The possibility of controlling a prosthetic device through a direct interface with the central nervous system represents a promising solution for restoring sensory-motor functionalities in patients with limb amputations or peripheral and neurological deficits due to spinal cord injury, amyotrophic lateral sclerosis, or stroke
In order to assess the performance of this system, we took the following steps: first we developed suitable spike-based decoding methods that could be implemented by the neuromorphic processor chip, we configured the chip to implement these methods in real-time and adapted the bidirectional brain-machine interfaces (BMIs) designed and tested in our lab (Vato et al, 2012) to include in the processing chain this neuromorphic component
Our work extends this approach in proposing a modular and reconfigurable scheme whereby the neuromorphic chip can be exploited for implementing different algorithms and BMI functions; in particular, we demonstrated this approach by using the chip as neural decoder
Summary
The possibility of controlling a prosthetic device through a direct interface with the central nervous system represents a promising solution for restoring sensory-motor functionalities in patients with limb amputations or peripheral and neurological deficits due to spinal cord injury, amyotrophic lateral sclerosis, or stroke. Neuromorphic BMI toward the clinical application of these devices Such interfaces offer a powerful tool for exploring the sensory-motor mechanisms of control, adaptation, and learning that are employed by the central nervous system. The development of a BMI system aiming for large clinical application requires crucial improvements of the hardware and software components. The hardware components need to be (a) fully implantable for long term use and miniaturizable; (b) able to reliably process neural signals with a limited power budget; (c) powerful enough to implement non-trivial computational tasks involved in a BMI system. The decoding algorithms need to be (d) sufficiently flexible to be implemented with different types of hardware components, and (e) able to dynamically adapt to changes in the neural activity due to the interaction with the artificial device (Dangi et al, 2011; Orsborn et al, 2014)
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