PubMed:22171043
Annnotations
Allie
| Id | Subject | Object | Predicate | Lexical cue |
|---|---|---|---|---|
| SS1_22171043_6_0 | 981-1003 | expanded | denotes | local field potentials |
| SS2_22171043_6_0 | 1005-1009 | abbr | denotes | LFPs |
| AE1_22171043_6_0 | SS1_22171043_6_0 | SS2_22171043_6_0 | abbreviatedTo | local field potentials,LFPs |
UseCases_ArguminSci_Discourse
| Id | Subject | Object | Predicate | Lexical cue |
|---|---|---|---|---|
| T1 | 0-88 | DRI_Outcome | denotes | Optimizing the decoding of movement goals from local field potentials in macaque cortex. |
| T2 | 89-228 | DRI_Outcome | denotes | The successful development of motor neuroprosthetic devices hinges on the ability to accurately and reliably decode signals from the brain. |
| T3 | 229-381 | DRI_Challenge | denotes | Motor neuroprostheses are widely investigated in behaving non-human primates, but technical constraints have limited progress in optimizing performance. |
| T4 | 382-539 | DRI_Background | denotes | In particular, the organization of movement-related neuronal activity across cortical layers remains poorly understood due, in part, to the widespread use of |
| T5 | 540-569 | Token_Label.OUTSIDE | denotes | fixed-geometry multielectrode |
| T6 | 570-577 | DRI_Background | denotes | arrays. |
| T7 | 578-753 | DRI_Approach | denotes | In this study, we use chronically implanted multielectrode arrays with individually movable electrodes to examine how the encoding of movement goals depends on cortical depth. |
| T8 | 754-946 | DRI_Approach | denotes | In a series of recordings spanning several months, we varied the depth of each electrode in the prearcuate gyrus of frontal cortex in two monkeys as they performed memory-guided eye movements. |
| T9 | 947-1113 | DRI_Outcome | denotes | We decode eye movement goals from local field potentials (LFPs) and multiunit spiking activity recorded across a range of depths up to 3 mm from the cortical surface. |
| T10 | 1114-1325 | DRI_Outcome | denotes | We show that both LFP and multiunit signals yield the highest decoding performance at superficial sites, within 0.5 mm of the cortical surface, while performance degrades substantially at sites deeper than 1 mm. |
| T11 | 1326-1473 | DRI_Outcome | denotes | We also analyze performance by varying bandpass filtering characteristics and simulating changes in microelectrode array channel count and density. |
| T12 | 1474-1518 | DRI_Outcome | denotes | The results indicate that the performance of |
| T13 | 1519-1544 | Token_Label.OUTSIDE | denotes | LFP-based neuroprostheses |
| T14 | 1545-1666 | DRI_Outcome | denotes | strongly depends on recording configuration and that recording depth is a critical parameter limiting system performance. |
PubMed_ArguminSci
| Id | Subject | Object | Predicate | Lexical cue |
|---|---|---|---|---|
| T1 | 89-228 | DRI_Outcome | denotes | The successful development of motor neuroprosthetic devices hinges on the ability to accurately and reliably decode signals from the brain. |
| T2 | 229-381 | DRI_Challenge | denotes | Motor neuroprostheses are widely investigated in behaving non-human primates, but technical constraints have limited progress in optimizing performance. |
| T3 | 382-539 | DRI_Background | denotes | In particular, the organization of movement-related neuronal activity across cortical layers remains poorly understood due, in part, to the widespread use of |
| T4 | 570-577 | DRI_Background | denotes | arrays. |
| T5 | 578-753 | DRI_Approach | denotes | In this study, we use chronically implanted multielectrode arrays with individually movable electrodes to examine how the encoding of movement goals depends on cortical depth. |
| T6 | 754-946 | DRI_Approach | denotes | In a series of recordings spanning several months, we varied the depth of each electrode in the prearcuate gyrus of frontal cortex in two monkeys as they performed memory-guided eye movements. |
| T7 | 947-1113 | DRI_Outcome | denotes | We decode eye movement goals from local field potentials (LFPs) and multiunit spiking activity recorded across a range of depths up to 3 mm from the cortical surface. |
| T8 | 1114-1325 | DRI_Outcome | denotes | We show that both LFP and multiunit signals yield the highest decoding performance at superficial sites, within 0.5 mm of the cortical surface, while performance degrades substantially at sites deeper than 1 mm. |
| T9 | 1326-1473 | DRI_Outcome | denotes | We also analyze performance by varying bandpass filtering characteristics and simulating changes in microelectrode array channel count and density. |
| T10 | 1474-1518 | DRI_Outcome | denotes | The results indicate that the performance of |
| T11 | 1545-1666 | DRI_Outcome | denotes | strongly depends on recording configuration and that recording depth is a critical parameter limiting system performance. |