ライフサイエンスコーパス: oculomotor nucleus

1 ibition of output from the (parasympathetic) oculomotor nucleus.

2 the caudal central subdivision (CCS) of the oculomotor nucleus.

3 S were found to project predominantly to the oculomotor nucleus.

4 led cells were revealed in the contralateral oculomotor nucleus.

5 y recording medial rectus motoneurons of the oculomotor nucleus.

6 ich lies rostral, dorsal, and ventral to the oculomotor nucleus.

7 re found caudally, dorsal and ventral to the oculomotor nucleus.

8 Within the oculomotor nucleus, a much sparser ipsilateral projectio

9 y inputs to medial rectus motoneurons in the oculomotor nucleus and are related to the control of con

10 stibular labyrinth, direct projection to the oculomotor nucleus and, in some cases, inhibition from c

11 ing on eye movements, gene expression in the oculomotor nucleus, and contractility of isolated extrao

12 in neurons of the nucleus raphe dorsalis and oculomotor nucleus, and occasionally in glia.

13 e MLF, the superior cerebellar peduncle, the oculomotor nucleus, and the interstitial nucleus of Caja

14 ) inputs to medial rectus motoneurons in the oculomotor nucleus are important for conjugate horizonta

15 of A- and B-group motoneurons lay within the oculomotor nucleus, but those of the C-group motoneurons

16 lar formation (cMRF), located lateral to the oculomotor nucleus, contains premotor neurons potentiall

17 stigate whether neuronal activity within the oculomotor nucleus could be driving the abnormal cross-a

18 In the oculomotor nucleus, CR was specifically found in punctat

19 a final common pathway, we found that in the oculomotor nucleus, distinct subsets of motoneurons were

20 ns with medial rectus motoneurons in the cat oculomotor nucleus have been examined by light and elect

21 ted ventrolaterally and rostrally within the oculomotor nucleus (III).

22 f vagus-induced activity that ascends to the oculomotor nucleus in the midbrain, we conclude that ESV

23 c neuron, interneuron, abducens nucleus, and oculomotor nucleus, is developed to examine saccade dyna

24 In the oculomotor nucleus, neuronal loss was seen only once in

25 Burst-tonic activity was recorded from oculomotor nucleus neurons in three animals with A-patte

26 ed when injections were localized within the oculomotor nucleus proper, without involving the CCS.

27 e, substantia nigra, ventral tegmental area, oculomotor nucleus, red nucleus, raphe nuclei, periaqued

28 ed nucleus, facial nucleus, pontine nucleus, oculomotor nucleus, substantia nigra, deep cerebellar nu

29 the CNS via retrograde transport through the oculomotor nucleus that innervates extraocular muscles o

30 ic nuclei, the pedunculopontine nucleus, the oculomotor nucleus, the hippocampal formation, and the f

31 s appeared in the pretectal olivary nucleus, oculomotor nucleus, the medial and lateral lemniscus, pe

32 ei, the trapezoid body, the red nucleus, the oculomotor nucleus, the vestibular nucleus, the cochlear

33 PCR, we found that dark rearing shifted the oculomotor nucleus transcriptome to a state of delayed/a

34 Burst-tonic activity of 21 MRMNs in the oculomotor nucleus were recorded from two monkeys with e

35 ie adjacent to the dorsomedial border of the oculomotor nucleus, whereas MR neurons are located farth