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1 submovements, and a distinct oscillation in premotor cortex.
2 ent had abnormally high activity in the left premotor cortex.
3 h the putamen increased connectivity through premotor cortex.
4 neurons in medial frontal cortex, likely in premotor cortex.
5 st-training gray matter volume in the dorsal premotor cortex.
6 rty first shown for mirror neurons in monkey premotor cortex.
7 g the superior temporal sulcus, parietal and premotor cortex.
8 esponses more frequently than stimulation in premotor cortex.
9 including the posterior parietal cortex and premotor cortex.
10 on that is no longer performed by the dorsal premotor cortex.
11 y cortex SII, posterior parietal cortex, and premotor cortex.
12 ervation conditions within the right ventral premotor cortex.
13 oded in the dorsal striatum and in the right premotor cortex.
14 appropriate activations of frontal motor and premotor cortex.
15 RI activity in posterior parietal and dorsal premotor cortex.
16 orsal, and is eventually centered around the premotor cortex.
17 used to define the motor goal in the PPC and premotor cortex.
18 ects following the application of TMS to the premotor cortex.
19 parietal regions, including bilateral dorsal premotor cortex.
20 right middle temporal gyrus (MTG), and right premotor cortex.
21 ginated in the lateral instead of the medial premotor cortex.
22 tissue loss in the right dorsal ACC and left premotor cortex.
23 multisensory areas, most notably the ventral premotor cortex.
24 ived, trajectories were found in the ventral premotor cortex.
25 ompassed both primary motor and the adjacent premotor cortex.
26 num temporale, superior parietal cortex, and premotor cortex.
27 e mediated by interactions between motor and premotor cortex.
28 not recover after bilateral silencing of the premotor cortex.
29 of neuron packing density include motor and premotor cortex.
30 cial cues modulate MNs in the monkey ventral premotor cortex.
31 n of decision-related firing rates in dorsal premotor cortex.
32 ferior temporal cortex as well as in ventral premotor cortex.
33 of Wernicke's area, Broca's area, and dorsal premotor cortex.
34 , occipitotemporal, parietal, cingulate, and premotor cortex.
35 d received dense projections from the medial premotor cortex.
36 eech and show focal degeneration of superior premotor cortex.
37 ns to the caudal and rostral areas of dorsal premotor cortex (6DC and 6DR, also known as F2 and F7) w
38 anding by recruitment of left dorsal lateral premotor cortex, a region normally devoted to higher-lev
41 ity patterns with parahippocampal cortex and premotor cortex again suggested fundamental corresponden
42 -a premotor area homologous to the mammalian premotor cortex-alters the statistics of the syllable se
43 nding motor pathway, where recordings from a premotor cortex analog nucleus reflected changes to temp
45 pattern of changes with relative ipsilateral premotor cortex and bilateral supplementary motor area a
47 xel patterns of activity in the left ventral premotor cortex and Broca's area exhibited effective pho
51 visuo-motor mirror neurons located in monkey premotor cortex and parietal cortices as well as homolog
52 arriers (p < 0.001, uncorrected) in the left premotor cortex and right supplementary motor area, with
53 lated with increases in fMRI activity in the premotor cortex and secondary somatosensory cortex contr
54 ng this EEG potential arises from the dorsal premotor cortex and serves an executive-attentional func
55 fective connectivity between the prefrontal, premotor cortex and SMA was not observed in patients.
57 26), with decreased BOLD activation in right premotor cortex and supplementary motor area and left hi
58 led focal hypometabolism of superior lateral premotor cortex and supplementary motor area, although t
60 integration of the two components in dorsal premotor cortex and supplementary motor areas, two regio
61 asting with the relative code seen in dorsal premotor cortex and the mostly gaze-centered reference f
62 , while many neurons in the dorsal aspect of premotor cortex and the primary motor cortex were simult
63 m the caudally adjacent ventral parts of the premotor cortex and the primary motor cortical region th
65 PN, respectively) in mouse sensory-motor and premotor cortex and to investigate quantitatively the po
66 amen, and thalamus, including the stimulated premotor cortex, and a larger increase in cerebellar rCB
67 tterns in right superior parietal lobule and premotor cortex, and also left frontopolar cortex, signi
68 rected), intraparietal sulcus, caudal dorsal premotor cortex, and cerebellar lobule VI (t >/= 4.18, w
69 nucleus, thalamus, supplementary motor area, premotor cortex, and dorsolateral prefrontal cortex duri
70 al visual cortex, posterior parietal cortex, premotor cortex, and hippocampus) and with activation of
71 al areas, relative to the shoulder in dorsal premotor cortex, and in muscle- or joint-based coordinat
72 rsolateral prefrontal cortex, bilaterally in premotor cortex, and in posterior parietal and occipital
73 rontal cortex (including Broca's area), left premotor cortex, and left and right posterior parietal c
75 d activity in the lateral cerebellum, dorsal premotor cortex, and parahippocampal gyrus, with covaryi
76 essening of activation in prefrontal cortex, premotor cortex, and posterior parietal cortex, areas th
77 xternally driven) in parietal cortex, dorsal premotor cortex, and primary motor cortex contralateral
78 ce data on premovement activity in motor and premotor cortex, and suggest that synaptic plasticity ma
79 production including inferior frontal gyrus, premotor cortex, and superior temporal gyrus during a pi
80 on at the single neuron level in the ventral premotor cortex, and support the hypothesis of a functio
82 of core motor regions comprising M1, lateral premotor cortex, and the supplementary motor area (SMA)
83 he primary motor cortex, the ventral lateral premotor cortex, and the supplementary motor area are es
84 the lateral premotor loop comprising lateral premotor cortex; and (iii) cortico-subcortical interacti
85 posterior inferior temporal cortex and right premotor cortex are consistent with neurophysiologically
87 m the dorsocaudal and medial subdivisions of premotor cortex (areas 6DC and 6M), from somatosensory a
88 xperiment 2, inhibitory stimulation of right premotor cortex as a key node of the dorsal stream decre
89 r area, and the caudal subdivision of dorsal premotor cortex, as well as afferents from cingulate are
90 rophy over time were observed throughout the premotor cortex, as well as prefrontal cortex, motor cor
91 inferior frontal gyrus and adjacent ventral premotor cortex, as well as the rostral inferior parieta
92 licated in the mirror neuron system, such as premotor cortex (BA 6) and inferior parietal lobule (BA
93 signed to test the idea that firing rates in premotor cortex become optimized during motor preparatio
94 grasping circuit', involving rostral ventral premotor cortex (Brodmann area 44) and intraparietal sul
95 vate widespread regions of frontal motor and premotor cortex but instead, produces focal, somatotopic
96 ompensatory relationship between putamen and premotor cortex by showing, in the control subjects, tha
97 related increases were seen in caudal dorsal premotor cortex, caudal cingulate sulcus, intraparietal
98 left dorsal inferior frontal gyrus and left premotor cortex, children who stutter exhibited deactiva
99 code actions at abstract levels whereas the premotor cortex codes actions at the concrete level only
100 ch to a visual target, neurons in the dorsal premotor cortex compare the location of the target, the
102 indicate that area F5 in the macaque ventral premotor cortex consists of three different sectors.
103 literature, we suggest that the left dorsal premotor cortex contributes to trajectory control, while
106 re prevalent in superficial layers of dorsal premotor cortex; deeper layers contained more "decreased
107 ion for decision-related responses in dorsal premotor cortex.Dorsal premotor cortex (PMd) is thought
108 (PPC), dorsal premotor cortex (PMd), ventral premotor cortex, dorsolateral prefrontal cortex, presupp
109 iven movement plans in contralateral ventral premotor cortex, dorsolateral prefrontal cortex, suprama
110 supplementary motor area (SMA), left dorsal premotor cortex (dPM), and left anterior cingulate corte
111 nt forms of motor simulation: (1) the dorsal premotor cortex (dPMC), associated with automatic motor
112 profiles of individual neurons in the dorsal premotor cortex during comparison of tactile temporal pa
113 ues and examined single neuron activities in premotor cortex during natural vocal exchanges in the co
114 ation (TMS) over the PPC, but not the dorsal premotor cortex, enhances this effect without affecting
116 iated responses to fearful faces in her left premotor cortex face area and bilaterally in the inferio
118 nnectivity between M1 and ipsilateral dorsal premotor cortex further increased dose-dependently after
119 gnetic stimulation (rTMS) to the left dorsal premotor cortex has a lasting influence on the excitabil
120 f "mirror neurons" in area F5 of the ventral premotor cortex has prompted many theories as to their p
122 Mirror neurons in area F5 of the monkey premotor cortex have been suggested to play a crucial ro
123 Corpus callosum bisections demonstrated that premotor cortex hemispheres can maintain preparatory act
124 se results show that the disruption of human premotor cortex impairs speech perception, thus demonstr
125 right inferior parietal cortex and bilateral premotor cortex, implicating these systems in attention
126 ibited the extrastriate body area and dorsal premotor cortex in 11 PD patients and 12 healthy subject
127 work, we use optogenetic stimulation of the premotor cortex in awake, behaving mice to demonstrate t
132 of the mouse cortex (a possible homologue of premotor cortex in primates) contains equal proportions
133 distinct from neighboring regions of ventral premotor cortex, in line with recent anatomical connecti
134 th left inferior parietal lobule and ventral premotor cortex, indicating that each LATL subregion exh
135 ing significantly more activation in ventral premotor cortex, inferior parietal cortex, and inferotem
137 temporal parietal occipital junction, dorsal premotor cortex, insula, and posterior cingulate cortex
138 show that, 200 ms after stimulus onset, the premotor cortex integrated gaze, gesture, and emotion di
139 n and motor preparation localized to lateral premotor cortex, intraparietal sulcus, and posterior sup
140 increased regional glucose metabolism in the premotor cortex ipsilateral to stimulation and in the ce
141 increased learning-related activation of the premotor cortex is compatible with the view of DYT1 dyst
142 lcium imaging reveal that neural activity in premotor cortex is correlated with a length scale of 100
144 area (AIP) and hand area (F5) of the ventral premotor cortex is implicated strongly in the generation
145 uggest that peri-hand space remapping in the premotor cortex is most tightly linked to the subjective
147 ively coupled modules, as we observed in the premotor cortex, is a hallmark of robust control systems
148 that this mechanism also operates in dorsal premotor cortex, largely accounting for how preparatory
149 ne set of regions (e.g., within left lateral premotor cortex; left precuneus; right posterior cerebel
151 projections were found from the dorsolateral premotor cortex (LPMCd), ventrolateral proisocortical mo
154 ty emerged during learning, originating from premotor cortex (M2), and M2 became predictive of the ac
156 reviously described within primary motor and premotor cortex may represent different types of actions
157 n show that neural populations in the medial premotor cortex (MPC) contain an accurate trial-by-trial
158 asked how oscillatory dynamics in the medial premotor cortex (MPC) contribute to supramodal perceptua
159 vioral data, ensemble recordings from medial premotor cortex (MPC) in macaque monkeys, and computatio
161 g accuracy of cell populations in the medial premotor cortex (MPC) of Rhesus monkeys to represent in
162 ural recording technique, we observed in the premotor cortex neural activation and suppression both b
163 study is the discovery of a subpopulation of premotor cortex neurons that was activated by vocal prod
165 terior intraparietal sulcus and left ventral premotor cortex; now, however, we also find activity for
166 thickness (VBCT) increases in the bilateral premotor cortex of hemiparetic patients relative to cont
167 e dataset recorded in the striatum and motor-premotor cortex of macaque monkeys performing reaching t
171 taneous microelectrode array recordings from premotor cortex of monkeys performing delayed-reach move
172 Integration of sensory-motor information in premotor cortex of rodents occurs largely through callos
173 nsistent with the hypothesis that the dorsal premotor cortex of the affected hemisphere can reorganiz
174 ost of the activity seen in the parietal and premotor cortex of the human brain is independent of mir
175 ruited areas in the visual dorsal stream and premotor cortex of the intact hemisphere to compensate f
176 hese patients, disruption of activity in the premotor cortex of the lesioned hemisphere by transcrani
178 particular, movement-related activity in the premotor cortex of the nonstimulated hemisphere increase
179 al variability of neural responses in dorsal premotor cortex of three monkeys performing a delayed-re
180 electrode arrays implanted in monkey dorsal premotor cortex, of a manyfold higher performance BCI th
181 tivity between prefrontal cortex and lateral premotor cortex OFF medication, compatible with a contex
182 he dorsolateral prefrontal cortex and dorsal premotor cortex onto the contralateral primary motor cor
183 motor-centric and cognitive accounts whether premotor cortex or brain regions in closer relation to p
184 when TMS was delivered over adjacent dorsal premotor cortex or when motor behaviors in late adaptati
186 posterior superior temporal sulcus, and left premotor cortex, OT increased activity during social jud
189 tion to the typical involvement of motor and premotor cortex, particularly pronounced pathological ch
190 provide evidence indicating that the dorsal premotor cortex plays a causal role in accurate turn-tak
193 tex (M1) and the secondary motor cortex: the premotor cortex (PMA) and the accessory motor area (SMA)
195 motor area (M1), primary sensory area (S1), premotor cortex (PMC) and supplementary motor area (SMA)
198 ing motor threshold, RMT) to the left dorsal premotor cortex (PMd) (CS2) suppresses the amplitude of
201 applied to the primary motor cortex, dorsal premotor cortex (PMd) and ventral premotor cortex (PMv)
202 reaching tasks with multiple targets, dorsal premotor cortex (PMd) appears to represent all possible
203 We applied single-pulse TMS to M1 or dorsal premotor cortex (PMd) during adaptation of rapid arm mov
205 ENT For reach-to-grasp movements, the dorsal premotor cortex (PMd) has been implicated in the control
207 indicate a prominent role of the left dorsal premotor cortex (PMd) in action selection based on learn
208 magnetic stimulation (rTMS) over the dorsal premotor cortex (PMd) in healthy subjects and in patient
211 d responses in dorsal premotor cortex.Dorsal premotor cortex (PMd) is thought to be involved in makin
212 nsorimotor hand area (SM1) and caudal dorsal premotor cortex (PMd) of the nondominant left hemisphere
213 and high multiunit activity of monkey dorsal premotor cortex (PMd) predicting forthcoming actions on
215 ion profiles in the precuneus and the dorsal premotor cortex (PMd) were indicative of an updating pro
216 (M1), supplementary motor area (SMA), dorsal premotor cortex (PMd), basal ganglia (BG), cerebellum (C
217 the posterior parietal cortex (PPC), dorsal premotor cortex (PMd), ventral premotor cortex, dorsolat
223 es of the parieto-frontal system: the dorsal premotor cortex (PMd, area 6), primary motor cortex (MI,
224 inent activation of the contralateral dorsal premotor cortex [PMd, Brodmann area (BA) 6] in multiple
225 ctivity of mirror neurons in macaque ventral premotor cortex (PMv) and primary motor cortex (M1) is m
226 nial magnetic stimulation (TMS) near ventral premotor cortex (PMv) and primary motor cortex (M1) with
227 in the inferior parietal lobule and ventral premotor cortex (PMv) can code the intentions of other i
228 interhemispheric connections of the ventral premotor cortex (PMv) distal forelimb representation (DF
229 ng movements of the arm, whereas the ventral premotor cortex (PMv) has been associated with the contr
230 ng movements of the arm, whereas the ventral premotor cortex (PMv) has been associated with the contr
232 rior intraparietal sulcus (aIPS) and ventral premotor cortex (PMv) in visually mediated state estimat
234 ex, dorsal premotor cortex (PMd) and ventral premotor cortex (PMv) of the affected (M1AH, PMdAH, PMvA
235 posterior parietal cortex (PPC) and ventral premotor cortex (PMv) represent the position of the uppe
238 es the pattern of connections of the ventral premotor cortex (PMv) with various cortical regions of t
242 an agent engaged the dorsal pathway and the premotor cortex, possibly to facilitate the preparation
243 lementary motor area, cingulate motor areas, premotor cortex, posterior parietal cortex, and cerebell
244 nd 7b, with the parietal rostroventral area, premotor cortex, posterior parietal cortex, and with the
245 am, the critical voxels were concentrated in premotor cortex, pre- and postcentral gyri and supramarg
246 ed in motor representation, including dorsal premotor cortex, pre-supplementary motor area, cerebellu
247 y integrated core circuit, spanning parts of premotor cortex, prefrontal cortex, temporal lobe, parie
248 act, including the supplementary motor area, premotor cortex, primary motor cortex, and midcingulate
249 in bilateral secondary somatosensory cortex, premotor cortex, primary motor cortex, insula and poster
251 uggests that multisensory integration in the premotor cortex provides a mechanism for bodily self-att
252 In contrast, inhibition of the left dorsal premotor cortex reduced the posture congruency effect in
254 vity of groups of neurons in primate ventral premotor cortex reflects information related to visually
258 t postcentral gyrus (rPoG) and right lateral premotor cortex (rPM) is involved in nonverbal auditory
259 ral premotor cortex (rPMv), the right dorsal premotor cortex (rPMd) or the supplementary motor area (
260 d over the right M1 (rM1), the right ventral premotor cortex (rPMv), the right dorsal premotor cortex
261 These findings provide clear evidence of the premotor cortex's involvement in self-initiated vocal pr
262 e observations provide clear evidence of the premotor cortex's involvement in vocal production in a N
263 ity in the dorsomedial prefrontal cortex and premotor cortex scaled with the cost of hierarchical pla
264 estimated white matter tract strength in the premotor cortex seeded from the posterior putamen (as we
268 bjects, the brain's mirror system-comprising premotor cortex, superior temporal sulcus and parietal c
269 motor activity and sound processing (dorsal premotor cortex, supplementary and pre-supplementary mot
270 activity in the sensorimotor cortex, dorsal premotor cortex, supplementary motor area and cerebellum
271 localized to the sensorimotor cortex, dorsal premotor cortex, supplementary motor area and the inferi
272 al, ventrolateral, and anterior PFC, lateral premotor cortex, supplementary motor area, and the stria
273 rior primary motor cortex (BA 4a), bilateral premotor cortex, supplementary motor area, intraparietal
274 t that the organization of the motor cortex, premotor cortex, supplementary motor cortex, frontal eye
275 bpopulations of neurons in the rhesus monkey premotor cortex that allow two planned targets of a sequ
276 neurons' are cells in area F5 of the ventral premotor cortex that are active during both observation
277 ed bilaterally a superior portion of ventral premotor cortex that largely overlapped a speech product
279 discriminated action potentials (spikes) in premotor cortex that triggered electrical stimulation in
280 ified a subpopulation of neurons in marmoset premotor cortex that was activated or suppressed by voca
281 r area and the rostral portion of the dorsal premotor cortex, the 'pre-PMd', are, in many respects, m
282 he primary motor cortex, the ventral lateral premotor cortex, the supplementary motor area on the med
283 esional cerebellum, and ipsilesional rostral premotor cortex, this relationship is seen only in the e
284 e left substantia nigra and the left lateral premotor cortex to be significantly more activated in th
285 ive transcranial magnetic stimulation to the premotor cortex to disrupt subjects' ability to perform
286 cted by variability of BOLD responses in the premotor cortex to far stimuli approaching our body.
287 y and optogenetic perturbations in the mouse premotor cortex to probe the robustness of persistent ne
288 quency (77-82 Hz) in a ventral region of the premotor cortex to produce a third rhythm at the sum of
289 x movements, and conclude that the motor and premotor cortex together may form a single map of comple
290 For example, trial-by-trial variability in premotor cortex tracks motor preparation with increasing
295 um, the supplementary eye fields, and dorsal premotor cortex, was found to be involved in generating
297 re is common neural activity in parietal and premotor cortex when executing and observing goal-direct
298 and in the population code of monkey dorsal premotor cortex when obstacles impeded direct reach path
299 of intraparietal sulcus and from the ventral premotor cortex, whereas medial PE forms denser connecti
300 ter the limb disturbance, and then in dorsal premotor cortex, with no effect in parietal regions unti
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