Detalhe da pesquisa
1.
Biological clockwork underlying adaptive rhythmic movements.
Proc Natl Acad Sci U S A
; 111(3): 978-83, 2014 Jan 21.
Artigo
em Inglês
| MEDLINE | ID: mdl-24395788
2.
The brain matters: effects of descending signals on motor control.
J Neurophysiol
; 107(10): 2730-41, 2012 May.
Artigo
em Inglês
| MEDLINE | ID: mdl-22378172
3.
Specialized brain regions and sensory inputs that control locomotion in leeches.
J Comp Physiol A Neuroethol Sens Neural Behav Physiol
; 198(2): 97-108, 2012 Feb.
Artigo
em Inglês
| MEDLINE | ID: mdl-22037913
4.
Mechanisms underlying rhythmic locomotion: interactions between activation, tension and body curvature waves.
J Exp Biol
; 215(Pt 2): 211-9, 2012 Jan 15.
Artigo
em Inglês
| MEDLINE | ID: mdl-22189764
5.
Dissociation of circadian and light inhibition of melatonin release through forced desynchronization in the rat.
Proc Natl Acad Sci U S A
; 106(41): 17540-5, 2009 Oct 13.
Artigo
em Inglês
| MEDLINE | ID: mdl-19805128
6.
Local-distributed integration by a novel neuron ensures rapid initiation of animal locomotion.
J Neurophysiol
; 105(1): 130-44, 2011 Jan.
Artigo
em Inglês
| MEDLINE | ID: mdl-20980540
7.
Mechanisms underlying rhythmic locomotion: dynamics of muscle activation.
J Exp Biol
; 214(Pt 11): 1955-64, 2011 Jun 01.
Artigo
em Inglês
| MEDLINE | ID: mdl-21562183
8.
Leech locomotion: swimming, crawling, and decisions.
Curr Opin Neurobiol
; 17(6): 704-11, 2007 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-18339544
9.
Multivariable harmonic balance analysis of the neuronal oscillator for leech swimming.
J Comput Neurosci
; 25(3): 583-606, 2008 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-18663565
10.
Neuronal control of leech behavior.
Prog Neurobiol
; 76(5): 279-327, 2005 Aug.
Artigo
em Inglês
| MEDLINE | ID: mdl-16260077
11.
Characterization of central axon terminals of putative stretch receptors in leeches.
J Comp Neurol
; 494(2): 290-302, 2006 Jan 10.
Artigo
em Inglês
| MEDLINE | ID: mdl-16320239
12.
A model for "splitting" of running-wheel activity in hamsters.
J Biol Rhythms
; 17(1): 76-88, 2002 Feb.
Artigo
em Inglês
| MEDLINE | ID: mdl-11837951
13.
Forced desynchronization of activity rhythms in a model of chronic jet lag in mice.
J Biol Rhythms
; 27(1): 59-69, 2012 Feb.
Artigo
em Inglês
| MEDLINE | ID: mdl-22306974
14.
Modeling two-oscillator circadian systems entrained by two environmental cycles.
PLoS One
; 6(8): e23895, 2011.
Artigo
em Inglês
| MEDLINE | ID: mdl-21886835
15.
Neuronal control of swimming behavior: comparison of vertebrate and invertebrate model systems.
Prog Neurobiol
; 93(2): 244-69, 2011 Feb.
Artigo
em Inglês
| MEDLINE | ID: mdl-21093529
16.
Corrections to the theory and the optimal line in the swimming diagram of Taylor (1952).
J R Soc Interface
; 7(49): 1243-6, 2010 Aug 06.
Artigo
em Inglês
| MEDLINE | ID: mdl-20597162
17.
Muscle function in animal movement: passive mechanical properties of leech muscle.
J Comp Physiol A Neuroethol Sens Neural Behav Physiol
; 193(12): 1205-19, 2007 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-17987298
18.
Model for intersegmental coordination of leech swimming: central and sensory mechanisms.
J Neurophysiol
; 87(6): 2760-9, 2002 Jun.
Artigo
em Inglês
| MEDLINE | ID: mdl-12037178
19.
Entrainment of leech swimming activity by the ventral stretch receptor.
J Comp Physiol A Neuroethol Sens Neural Behav Physiol
; 190(11): 939-49, 2004 Nov.
Artigo
em Inglês
| MEDLINE | ID: mdl-15338181
20.
Analysis of the optimal channel density of the squid giant axon using a reparameterized Hodgkin-Huxley model.
J Neurophysiol
; 91(6): 2541-50, 2004 Jun.
Artigo
em Inglês
| MEDLINE | ID: mdl-14749318