OBJECTIVE: Brain-computer interfaces (BCIs) are a promising technology for restoring motor ability to paralyzed patients. Spiking-based BCIs have successfully been used in clinical trials to control multi-degree-of-freedom robotic devices. Current implementations of these devices require a lengthy spike-sorting step, which is an obstacle to moving this technology from the lab to the clinic. A viable alternative is to avoid spike-sorting, treating all threshold crossings of the voltage waveform on an electrode as coming from one putative neuron. It is not known, however, how much decoding information might be lost by ignoring spike identity. APPROACH: We present a full analysis of the effects of spike-sorting schemes on decoding performance. Specifically, we compare how well two common decoders, the optimal linear estimator and the Kalman filter, reconstruct the arm movements of non-human primates performing reaching tasks, when receiving input from various sorting schemes. The schemes we tested included: using threshold crossings without spike-sorting; expert-sorting discarding the noise; expert-sorting, including the noise as if it were another neuron; and automatic spike-sorting using waveform features. We also decoded from a joint statistical model for the waveforms and tuning curves, which does not involve an explicit spike-sorting step. MAIN RESULTS: Discarding the threshold crossings that cannot be assigned to neurons degrades decoding: no spikes should be discarded. Decoding based on spike-sorted units outperforms decoding based on electrodes voltage crossings: spike-sorting is useful. The four waveform based spike-sorting methods tested here yield similar decoding efficiencies: a fast and simple method is competitive. Decoding using the joint waveform and tuning model shows promise but is not consistently superior. SIGNIFICANCE: Our results indicate that simple automated spike-sorting performs as well as the more computationally or manually intensive methods used here. Even basic spike-sorting adds value to the low-threshold waveform-crossing methods often employed in BCI decoding.
OBJECTIVE: Brain-computer interfaces (BCIs) are a promising technology for restoring motor ability to paralyzedpatients. Spiking-based BCIs have successfully been used in clinical trials to control multi-degree-of-freedom robotic devices. Current implementations of these devices require a lengthy spike-sorting step, which is an obstacle to moving this technology from the lab to the clinic. A viable alternative is to avoid spike-sorting, treating all threshold crossings of the voltage waveform on an electrode as coming from one putative neuron. It is not known, however, how much decoding information might be lost by ignoring spike identity. APPROACH: We present a full analysis of the effects of spike-sorting schemes on decoding performance. Specifically, we compare how well two common decoders, the optimal linear estimator and the Kalman filter, reconstruct the arm movements of non-human primates performing reaching tasks, when receiving input from various sorting schemes. The schemes we tested included: using threshold crossings without spike-sorting; expert-sorting discarding the noise; expert-sorting, including the noise as if it were another neuron; and automatic spike-sorting using waveform features. We also decoded from a joint statistical model for the waveforms and tuning curves, which does not involve an explicit spike-sorting step. MAIN RESULTS: Discarding the threshold crossings that cannot be assigned to neurons degrades decoding: no spikes should be discarded. Decoding based on spike-sorted units outperforms decoding based on electrodes voltage crossings: spike-sorting is useful. The four waveform based spike-sorting methods tested here yield similar decoding efficiencies: a fast and simple method is competitive. Decoding using the joint waveform and tuning model shows promise but is not consistently superior. SIGNIFICANCE: Our results indicate that simple automated spike-sorting performs as well as the more computationally or manually intensive methods used here. Even basic spike-sorting adds value to the low-threshold waveform-crossing methods often employed in BCI decoding.
Authors: Amy L Orsborn; Siddharth Dangi; Helene G Moorman; Jose M Carmena Journal: IEEE Trans Neural Syst Rehabil Eng Date: 2012-07 Impact factor: 3.802
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Authors: Mijail D Serruya; Nicholas G Hatsopoulos; Liam Paninski; Matthew R Fellows; John P Donoghue Journal: Nature Date: 2002-03-14 Impact factor: 49.962
Authors: Leigh R Hochberg; Daniel Bacher; Beata Jarosiewicz; Nicolas Y Masse; John D Simeral; Joern Vogel; Sami Haddadin; Jie Liu; Sydney S Cash; Patrick van der Smagt; John P Donoghue Journal: Nature Date: 2012-05-16 Impact factor: 49.962
Authors: Breanne P Christie; Derek M Tat; Zachary T Irwin; Vikash Gilja; Paul Nuyujukian; Justin D Foster; Stephen I Ryu; Krishna V Shenoy; David E Thompson; Cynthia A Chestek Journal: J Neural Eng Date: 2014-12-11 Impact factor: 5.379
Authors: Eric M Trautmann; Sergey D Stavisky; Subhaneil Lahiri; Katherine C Ames; Matthew T Kaufman; Daniel J O'Shea; Saurabh Vyas; Xulu Sun; Stephen I Ryu; Surya Ganguli; Krishna V Shenoy Journal: Neuron Date: 2019-06-03 Impact factor: 17.173
Authors: Nir Even-Chen; Dante G Muratore; Sergey D Stavisky; Leigh R Hochberg; Jaimie M Henderson; Boris Murmann; Krishna V Shenoy Journal: Nat Biomed Eng Date: 2020-08-03 Impact factor: 25.671
Authors: Emily R Oby; Sagi Perel; Patrick T Sadtler; Douglas A Ruff; Jessica L Mischel; David F Montez; Marlene R Cohen; Aaron P Batista; Steven M Chase Journal: J Neural Eng Date: 2016-04-21 Impact factor: 5.379