AI Article Synopsis
- Future neural interfaces capable of recording thousands of neurons can enhance our understanding and restoration of neural functions, but face challenges in data management and power consumption.
- The wired-OR compressive readout architecture helps tackle the overwhelming data volume by employing lossy compression at the analog-to-digital conversion stage, allowing for effective spike detection and waveform estimation.
- Tests on macaque retina recordings show that wired-OR can achieve over 50× compression while accurately detecting spikes, and when combined with a lossless compressor, can reach up to 1000× compression.
Article Abstract
Future high-density and high channel count neural interfaces that enable simultaneous recording of tens of thousands of neurons will provide a gateway to study, restore and augment neural functions. However, building such technology within the bit-rate limit and power budget of a fully implantable device is challenging. The wired-OR compressive readout architecture addresses the data deluge challenge of a high channel count neural interface using lossy compression at the analog-to-digital interface. In this article, we assess the suitability of wired-OR for several steps that are important for neuroengineering, including spike detection, spike assignment and waveform estimation. For various wiring configurations of wired-OR and assumptions about the quality of the underlying signal, we characterize the trade-off between compression ratio and task-specific signal fidelity metrics. Using data from 18 large-scale microelectrode array recordings in macaque retina ex vivo, we find that for an event SNR of 7-10, wired-OR correctly detects and assigns at least 80% of the spikes with at least 50× compression. The wired-OR approach also robustly encodes action potential waveform information, enabling downstream processing such as cell-type classification. Finally, we show that by applying an LZ77-based lossless compressor (gzip) to the output of the wired-OR architecture, 1000× compression can be achieved over the baseline recordings.
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| http://dx.doi.org/10.1109/TBCAS.2023.3292058 | DOI Listing |
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