Single cell and multiunit signals were recorded by a multichannel recording system (Plexon Inc, Texas) from 96 paralyne coated tungsten or platinum/iridium electrodes (impedance ≈ 300 kΩ) (Microprobe Inc. Maryland) implanted in the medial intraparietal area (MIP), a subdivision of the parietal reach region (PRR), and area 5 (1) of three rhesus monkeys trained to perform a memory reach task. One monkey (monkey S) also had 64 electrodes implanted in the dorsal premotor area (PMd) in a separate surgery. Each session consisted of a reach segment and a brain control segment. Trials in both segments were initiated in the same way: after the monkeys acquired a central red fixation point with the eyes and touched a central green target, a peripheral cue was flashed indicating the location of one out of four, five, six, or eight reach targets ( Figure 1a) (cue epoch). Reach targets were uniformly distributed around the central fixation point. As soon as the fixation point and central green target were acquired, hand and eye movements were restricted by a real time behavioural controller (LabVIEW, National Instruments). Eye position was monitored using a scleral search coil (CNC Engineering, monkeys S and O), or an infrared reflection system (ISCAN, monkey C) while hand position was monitored using an acoustic touch screen (ELO Touch). In order to successfully complete a trial, the monkeys were not allowed to move their eyes. In addition, the reaching hand had to be in contact with the centrally located green target at all times except after the GO signal which appeared during the reach segment of the session. After the offset of the cue, a delay of 1.5 ± 0.3 seconds ensued. During the reach segment, the green central target was extinguished after the memory period
This study demonstrated that an array of 96 microelectrodes can be implanted into the human peripheral nervous system for up to 1 month durations. Such an array could provide intuitive control of a virtual prosthetic hand with broad sensory feedback.
The extensive distribution and simultaneous termination of seizures across cortical areas has led to the hypothesis that seizures are caused by large-scale coordinated networks spanning these areas. This view, however, is difficult to reconcile with most proposed mechanisms of seizure spread and termination, which operate on a cellular scale. We hypothesize that seizures evolve into self-organized structures wherein a small seizing territory projects high-intensity electrical signals over a broad cortical area. Here we investigate human seizures on both small and large electrophysiological scales. We show that the migrating edge of the seizing territory is the source of travelling waves of synaptic activity into adjacent cortical areas. As the seizure progresses, slow dynamics in induced activity from these waves indicate a weakening and eventual failure of their source. These observations support a parsimonious theory for how large-scale evolution and termination of seizures are driven from a small, migrating cortical area.
Pathological conditions such as amyotrophic lateral sclerosis or damage to the brainstem can leave patients severely paralyzed but fully aware, in a condition known as "locked-in syndrome." Communication in this state is often reduced to selecting individual letters or words by arduous residual movements. More intuitive and rapid communication may be restored by directly interfacing with language areas of the cerebral cortex. We used a grid of closely spaced, nonpenetrating microelectrodes to record local field potentials (LFPs) from the surface of face motor cortex and Wernicke's area. From these LFPs we were successful in classifying a small set of words on a trial-by-trial basis at levels well above chance. We found that the pattern of electrodes with the highest accuracy changed for each word, which supports the idea that closely spaced micro-electrodes are capable of capturing neural signals from independent neural processing assemblies. These results further support using cortical surface potentials (electrocorticography) in brain-computer interfaces. These results also show that LFPs recorded from the cortical surface (micro-electrocorticography) of language areas can be used to classify speech-related cortical rhythms and potentially restore communication to locked-in patients.
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