ライフサイエンスコーパス: supplementary eye field

1 l sulcus (IPS), frontal eye field (FEF), and supplementary eye field.

2 mate frontal cortices such as the frontal or supplementary eye fields.

3 Here we show, using recordings from the supplementary eye field (a frontal cortex oculomotor cen

4 and neural spiking across all layers of the supplementary eye field, an agranular cortical area, in

5 onses and local-field potentials recorded in supplementary eye field and anterior cingulate cortex of

6 In the supplementary eye field and anterior cingulate cortex, n

7 In contrast, regions, such as supplementary eye fields and frontal eye fields, showed

8 network of three areas, the cerebellum, the supplementary eye fields, and dorsal premotor cortex, wa

9 These results demonstrate that the supplementary eye field can exert contextual executive c

10 mentary motor cortex, frontal eye field, and supplementary eye field can in principle be understood a

11 ad us to put forward the hypothesis that the supplementary eye field contributes to monitoring the co

12 ry motor area (pre-SMA) and a portion of the supplementary eye fields correlated with antisaccade lat

13 frontal gyrus (pre-supplementary motor area/supplementary eye field), dorsolateral prefrontal cortex

14 a frontal area that lacks granular layer IV, supplementary eye field, exhibits features of laminar ci

15 The supplementary eye field has the biggest say in choosing

16 sally placed presupplementary motor area and supplementary eye field have been implicated in direct e

17 Weak microstimulation of many sites in the supplementary eye field improved monkeys' performance on

18 To investigate the role of the supplementary eye field in the control of eye movements,

19 In monkeys, the supplementary eye field in the dorsomedial frontal corte

20 ntegrity of the presupplementary motion area/supplementary eye fields is critical for supervisory pro

21 These results suggest that the supplementary eye field might play a unique role in enco

22 e field, dorsolateral prefrontal cortex, and supplementary eye field of monkeys (Macaca mulatta) that

23 Studies of the supplementary eye field of the monkey have revealed that

24 microstimulation, we determined whether the supplementary eye field only monitors or can actually in

25 The supplementary eye field registers the occurrence of conf

26 s, we observed an abrupt transient change in supplementary eye field (SEF) activity when animals were

27 How supplementary eye field (SEF) contributes to visual sear

28 rocess by recording neuronal activity in the supplementary eye field (SEF) during an oculomotor gambl

29 upward followed by leftward), neurons in the supplementary eye field (SEF) fire differentially in con

30 on on human subjects to test the role of the supplementary eye field (SEF) in the proactive control o

31 e assessed the preferred directions (PDs) of supplementary eye field (SEF) neurons during conditional

32 stigated this question by recording from the supplementary eye field (SEF) of monkeys during a gambli

33 Label in a region corresponding to supplementary eye field (SEF) of other primates, suggest

34 rated previously that neurons in the macaque supplementary eye field (SEF) reflect the rule of ocular

35 Within the medial frontal cortex, the supplementary eye field (SEF), supplementary motor area

36 ly guided saccadic eye movements, namely the supplementary eye field (SEF).

37 and neural spiking across all layers of the supplementary eye field (SEF).

38 al oculomotor network, including frontal and supplementary eye fields (SEFs), and the striatum was ob

39 recordings, the LFP activity recorded in the supplementary eye field shared temporal characteristics

40 that included the frontal eye fields (FEFs), supplementary eye fields (SMA/SEFs), prefrontal cortex (

41 dorsal, and medial RTP from the frontal and supplementary eye fields, the superior colliculus, and t

42 ddition, signals for rewarded choices in the supplementary eye field were attenuated during the visua