Biology Reference
In-Depth Information
[100]Aizenman, C., Manis, P., Linden, D. (1998). Polarity Of Long-Term Synaptic Gain
Change Is Related To Postsynaptic Spike Firing At A Cerebellar Inhibitory Synapse.
Neuron
, 21, 827-835.
[101]Ouardouz, M., Sastry, B. (2000). Mechanisms Underlying Ltp Of Inhibitory Synaptic
Transmission In The Deep Cerebellar Nuclei.
J Neurophysiol
, 84, 1414-1421.
[102]Morishita, W., Sastry, B. (1996). Postsynaptic Mechanisms Underlying Long-Term
Depression Of Gabaergic Transmission In Neurons Of The Deep Cerebellar Nuclei.
J
Neurophysiol,
76, 59-68.
[103]Jahnsen, H. (1986). Electrophysiological Characteristics Of Neurones In The Guinea-
Pig Deep Cerebellar Nuclei In Vitro.
J Physiol
, 372, 129-147.
[104]Aizenman, C., Linden, D. (1999). Regulation Of The Rebound Depolarization And
Spontaneous Firing Patterns Of Deep Nuclear Neurons In Slices Of Rat Cerebellum.
J
Neurophysiol,
82, 1697-1709.
[105]Bienenstock, E., Cooper, L., Munro, P. (1982). Theory For The Development Of
Neuron Selectivity: Orientation Specificity And Binocular Interaction In Visual Cortex.
J Neurosci,
2, 32-48.
[106]Hansel, C., Artola, A., Singer, W. (1997). Relation Between Dendritic Ca
2+
Levels And
The Polarity Of Synaptic Long-Term Modifications In Rat Visual Cortex Neurons.
Eur
J Neurosci
, 9, 2309-2322.
[107]Pugh, J., Raman, I. (2006). Potentiation Of Mossy Fiber Epscs In The Cerebellar Nuclei
By Nmda Receptor Activation Followed By Postinhibitory Rebound Current.
Neuron,
51, 113-123.
[108]Zhang, W., Linden, D.
(2006). Long-Term Depression At The Mossy Fiber-Deep
Cerebellar Nucleus Synapse.
J Neurosci,
26, 6935-6944.
[109]Anchisi, D., Scelfo, B., Tempia, F. (2001). Postsynaptic Currents In Deep Cerebellar
Nuclei.
J Neurophysiol,
85, 323-331.
[110]Robinson, D. (1981). The Use Of Control Systems Analysis In The Neurophysiology Of
Eye Movements.
Annu Rev Neurosci
, 4, 463-503.
[111]Ito, M. (1982). Cerebellar Control Of The Vestibulo-Ocular Reflex--Around The
Flocculus Hypothesis.
Annu Rev Neurosci
, 5, 275-296.
[112]Nagao, S. (1988). Behavior Of Floccular Purkinje Cells Correlated With Adaptation Of
Horizontal Optokinetic Eye Movement Response In Pigmented Rabbits.
Exp Brain Res
,
73, 489-497.
[113]Boyden, E., Katoh, A., Raymond, J. (2004). Cerebellum-Dependent Learning: The Role
Of Multiple Plasticity Mechanisms.
Annu Rev Neurosci
, 27, 581-609.
[114]Ito, M., Jastreboff, P., Miyashita, Y. (1982). Specific Effects Of Unilateral Lesions In
The Flocculus Upon Eye Movements In Albino Rabbits.
Exp Brain Res
, 45, 233-242.
[115]Luebke, A., Robinson, D. (1994). Gain Changes Of The Cat's Vestibulo-Ocular Reflex
After Flocculus Deactivation.
Exp Brain Res
, 98, 379-390.
[116]Graf, W., Simpson, J.I., Leonard, C.S. (1988). Spatial Organization Of Visual Messages
Of The Rabbit's Cerebellar Flocculus. Ii. Complex And Simple Spike Responses Of
Purkinje Cells.
J Neurophysiol
, 60, 2091-2121.
[117]Miles, F., Lisberger, S. (1981). Plasticity In The Vestibulo-Ocular Reflex: A New
Hypothesis.
Annu Rev Neurosci
, 4, 273-299.
[118]Hirata, Y., Highstein, S. (2001). Acute Adaptation Of The Vestibuloocular Reflex:
Signal Processing By Floccular And Ventral Parafloccular Purkinje Cells.
J
Neurophysiol,
85, 2267-2288.
[119]Van Alphen, A.M., De Zeeuw, C.I. (2002). Cerebellar Ltd Facilitates But Is Not
Essential For Long-Term Adaptation Of The Vestibulo-Ocular Reflex.
European
Journal Of Neuroscience
, 16, 486-490.