Vladimir Marlinski publications
Research
papers:
1. Beloozerova IN, Marlinski V. Contribution of the ventrolateral thalamus to the locomotion-related activity of motor cortex. J. Neurophysiol., 124(5): 1480-1504, 2020. link
2. Toosizadeh N, Mohler J, Marlinski V. Low intensity vibration of ankle muscles improves balance in elderly persons at high risk of falling. PLoS One,13(3): e0194720, 2018. PDF
3. Ehsani H, Mohler J, Marlinski V, Rashedi E, Toosizadeh N. The influence of mechanical vibration on local and central balance control. J Biomech, 71: 59-66, 2018. link
4. Chu MI,
Seto SH, Beloozerova IN, Marlinski V. Strategies for
obstacle avoidance during walking in the cat. J. Neurophysiol.,
118(2): 817-831, 2017.
5. Marlinski V,
Beloozerova IN.
Burst firing of neurons in the thalamic reticular nucleus during locmotion. J.
Neurophysiol.,
6. Marlinski V, Sirota MG, Beloozerova IN. Differential gating of thalamo-cortical signals by reticular nucleus of thalamus during locomotion. J.Neurosci., 32(45): 15823-15836, 2012. PDF
7. Marlinski V, Nilaweera WU, Zelenin PV, Sirota MG, Beloozerova IN.
Signals from the ventrolateral thalamus to the
motor cortex during locomotion. J. Neurophysiol., 107(1):
455-472, 2012. PDF
8. Marlinski VV. Il'a Faddeevich Tsion--pioneer of vestibular physiology. Fiziol Zh., 58(2): 101-105, 2012. [In Russian.] PDF
9.
Marlinski V,
McCrea RA. Self-motion signals in vestibular nuclei neurons projecting to the
thalamus in the alert squirrel monkey. J Neurophysiol., 101(4): 1730-1741, 2009. PDF
10. Marlinski V,
McCrea RA. Coding of self-motion signals in ventro-posterior
thalamus in the alert squirrel monkey. Exp. Brain Res., 189: 463-472,
2008. link
11. Marlinski V,
McCrea RA. Activity of ventro-posterior thalamus
neurons during rotation and translation in the horizontal plane in the alert
squirrel monkey. J. Neurophysiol., 99:
2533-2545, 2008. PDF
12. Plotnik M, Marlinski V, Goldberg JM. Efferent-mediated
fluctuations in vestibular-nerve discharge: a novel, positive-feedback
mechanism of efferent control. J. Assoc. Res. Otolaryngol.,
6: 311-323, 2005. PDF
13. Marlinski
V, Plotnik M, Goldberg JM.
Efferent actions in the chinchilla vestibular labyrinth. J. Assoc. Res. Otolaryngol., 5: 126-143, 2004. PDF
14. Plotnik
M, Marlinski V, Goldberg JM.
Reflections of efferent activity in rotational responses of chinchilla
vestibular afferents. J. Neurophysiol., 88:
1234-1244, 2002. PDF
15. Plotnik
M, Marlinski V, Goldberg JM. Efferent
mediated binaural interactions between the vestibular end-organs in the
chinchilla. Ann.N.Y.Acad.Sci., 942: 479-481, 2001. link
16. Marlinsky VV,
Kroller J. Optokinetic eye
movements elicited by an apparently moving visual pattern in guinea pigs. Exp.
Brain Res., 131: 350-358, 2000. link
17. Marlinsky VV,
Reber M, Kroeller J. The
effect of d-amphetamine on optokinetic nystagmus in the guinea pig. J. Vestib.
Res., 9: 127-133, 1999. link
18. Marlinsky VV.
Vestibular and vestibulo-proprioceptive perception of
motion in the horizontal plane in blindfolded man. III. Route inference. Neuroscience,
90:403-412, 1999. link
19. Marlinsky VV.
Vestibular and vestibulo-proprioceptive perception of
motion in the horizontal plane in blindfolded man. II. Estimations of rotations
about the earth-vertical axis. Neuroscience, 90: 395-402, 1999. link
20. Marlinsky VV.
Vestibular and vestibulo-proprioceptive perception of
motion in the horizontal plane in blindfolded man. I. Estimations of linear
displacement. Neuroscience, 90: 389-394, 1999. link
21. Kroeller J, Behrens
F, Marlinsky VV. The velocity storage
mechanism of the optokinetic nystagmus
under apparent stimulus movements in squirrel monkeys. J. Vestib. Res., 7: 1-11, 1997. link
22. Marlinsky VV.
The effect of somatosensory stimulation on the second-order and efferent
vestibular neurons in the decerebrate guinea pig. Neuroscience,
69: 661-669, 1995. link
23. Marlinsky VV.
Activity of lateral vestibular nucleus neurons during locomotion in the decerebrate guinea pig. Exp. Brain Res., 90:
583-588, 1992. link
24. Marlinskii VV,
Voitenko LP. Participation of the medial reticular
formation of the medulla oblongata in the supraspinal
control of locomotor and postural activities in the
guinea pig. Neurosci. Behav.
Physiol., 22: 336-342, 1992. link
25. Marlinskii VV.
Activity of neurons of the guinea pig lateral vestibular nucleus evoked by
tilting about a longitudinal axis during locomotion. Neirofiziologiia,
1991, 23, 541-549, 1991. [In
Russian] link
26. Marlinskii VV.
Impulse activity of neurons of the lateral vestibular nucleus in guinea pigs
during locomotion. Neirofiziologiia, 23:
536-541, 1991. [In Russian] link
27. Marlinsky VV,
Voitenko LP. The effect of procaine injection into
the medullary reticular formation on forelimb muscle
activity evoked by mesencehpalic locomotor
region and vestibular stimulation in the decerebrated
guinea pig. Neuroscience, 45: 753-759, 1991. link
28. Marlinskii VV,
Tsintsababse FI. Activity of forelimb muscles under
vestibular stimulation in guinea pigs with cerebellum removed. Neurosci. Behav.
Physiol., 20: 388-394, 1990. link
29. Voitenko LP, Manko VV, Marlinskii VV.
The microinjection of novocaine into the giant-cell
nucleus of the medulla oblongata: the effect on the initiation of locomotor rhythms. Neirofiziologiia,
22: 565-567, 1990. [In Russian] link
30. Marlinskii VV,
Tsintsabadze FI. The effect of adequate stimulation
of the vestibular apparatus on evoked rhythmic activity in the nerves of the
forelimbs in the immobilized guinea pig. Neirofiziologiia,
22: 223-227, 1990. [In Russian] link
31. Marlinsky VV.
The influence of adequate vestibular stimulation on evoked locomotor
muscle activity in the decerebrated guinea pig. Neuroscience,
33: 643-650, 1989. link
32. Marlinskii VV,
Tsintsabadse FI. Effect of adequate stimulation of
the vestibular apparatus on the locomotor activity of
the fore- and hindlimb muscles in guinea pigs.
Movements relative to the vertical axis. Neirofiziologiia,
21: 192-197, 1989. [In Russian] link
33. Marlinskii VV,
Preobrazhensky NN, Seleznyov
VV, Shumilina VF. Influence of the efferent
vestibular system on the vestibulo-spinal reflexes in
the guinea pig. Neirofiziologiia, 21:
78-86, 1989. [In Russian] link
34. Marlinskii VV,
Tsintsabadze FI. Effect of adequate stimulation of
the vestibular apparatus on the locomotor activity of
the muscles in the fore- and hindlimbs of the guinea
pig. Rotation relative to the transverse axis. Neirofiziologiia,
19: 833-838, 1987. [In Russian] link
35. Marlinskii VV,
Voitenko LP. Dynamic properties of postural reflexes
of the neck in the cat. Neirofiziologiia, 19:
688-691, 1987. [In Russian] link
36. Marlinskii VV,
Tsintsabadze FI. Effect of adequate stimulation of
the vestibular apparatus on the locomotor activity of
the hindlimb muscles in the guinea pig. Rotations
relative to the longitudinal axis. Neirofiziologiia,
19: 549-551, 1987. [In Russian] link
37. Marlinskii VV,
Tsintsabadze FI. Effect of adequate stimulation of
the vestibular apparatus on the locomotor activity of
the forelimb muscles in the guinea pig. Rotations relative to the longitudinal
axis. Neirofiziologiia, 19: 534-541, 1987.
[In Russian] link
38. Marlinskii VV,
Tsintsabadze FI. Changes in the locomotor
activity of muscles of the forelimb of the guinea pig during translation of the
animal with respect to the longitudinal axis. Neirofiziologiia,
18: 409-412, 1986. [In Russian] link
39. Marlinskii VV,
Esipenko VB. Phase-frequency characteristics of
afferent activity and depolarization of primary afferents during passive
displacement of the hindlimb of the cat. Neirofiziologiia, 17: 701-703, 1985 [In Russian] link
40. Marlinskii VV,
Esipenko VB. Depolarization of primary afferents
evoked by cyclically modulated natural activity of proprioceptors
of the hindlimb of the cat. Neirofiziologiia,
17: 372-380, 1985 [In Russian] link
41. Marlinskii VV.
Depolarization of primary afferents induced by evoked activation of intersegmental connections of the substantia
gelatinosa of the spinal cord in the cat. Neirofiziologiia, 15: 288-294, 1983. [In Russian] link
42. Bayev
KV, Vasilenko DA, Marlinskii VV. Depolarization
of primary afferents induced by selective activation of propriospinal
tracts. Neirofiziologiia, 15: 71-77, 1983.
[In Russian] link
43. Korogod SM, Kostyukov AI, Marlinskii
VV. Dynamics of changes in the amplitude of the N1-component of the cord
dorsum potential during frequency-modulated stimulation of peripheral
afferents. Neirofiziologiia, 14: 201-203,
1982. [In Russian] link
44. Marlinskii VV.
Depolarization of primary forelimb afferents in the cat evoked by activation of
sensory nerves of the neck. Neirofiziologiia,
14(2): 190-197, 1982. [In
Russian] link
45. Kostyukov AI, Marlinskii VV. Certain
nonlinear properties of motor reactions induced by motor cortex stimulation in
the unanesthetized cat. Neirofiziologiia,
13: 218-220, 1981. [In Russian] link
46. Kostyukov AI, Marlinskii VV. Frequency analysis of motor
reactions induced by stimulation of the motor cortex in unanaesthetized
cats. Neirofiziologiia, 12: 571-579, 1980.
[In Russian] link
47. Kostyukov AI, Marlinskii VV. Dynamic characteristics of
motor reactions induced by motor cortex stimulation of unanesthetized
cats. Neirofiziologiia, 12: 451-458, 1980.
[In Russian] link
48. Vasilenko DA, Marlinskii VV. Polysynaptic effects in
neurons of the cervical portion of the cat spinal cord induced by activation of
long propriospinal pathways. Neirofiziologiia,
11: 339-347, 1979. [In Russian] link
Book, Book chapter, Review:
1.
Voitenko
LP, Marlinsky VV. Stereotaxic
atlas of the guinea pig brainstem. Naukova Dumka,
2.
Marlinsky VV, Vasilenko DA,
Tsintsabadze FI. Modulation of locomotor
activity induced by natural stimulation of the vestibular system. In: Stance
and Motion: Facts and Concepts. Plenum Press, p. 143-151, 1988.
3.
Marlinskii
VV. Depolarization of primary afferents in the spinal
cord. Mechanisms and functions. Neirofiziologiia,
14: 543-552, 1982. [In Russian] link
