Adaptive changes in vergence eye movements induced by vergence-vestibular interaction training in monkeys

Clear vision of objects moving in three-dimensional space near an observer is attained by a combination of smooth-pursuit and vergence eye movements. The two systems must interact with the vestibular system to maintain the image of the object on the fovea. Previous studies showed that training with smooth-pursuit vestibular interactions resulted in adaptive changes in the smooth-pursuit response. Although vergence and smooth-pursuit systems are thought to have separate neural substrates, recent studies indicate that the caudal parts of the frontal eye fields that receive vestibular inputs contain neurons that discharge in response to combinations of smooth-pursuit and vergence. This combination of discharge sensitivities suggests the possibility that adaptive changes may be induced in the vergence system by vestibular inputs during vergence-pursuit training. To explore this possibility, we examined the effects of training with conflicting vestibular and vergence tracking in four head-stabilized monkeys. Animals were rewarded for tracking a laser spot that moved towards or away from them at 1 Hz in phase with sinusoidal whole-body rotation (±5°) in the pitch plane; the spot moved closer when the monkeys nose moved downward. From the monkeys point of view, the spot moved sinusoidally 10–66 cm in front of them along the mid-sagittal plane, requiring symmetrical vergence eye movements of 4.8° for each eye. Eye movements induced by equivalent spot motion at 0.3–1.0 Hz with or without chair rotation were examined before and after training for each session (0.5–1.0 h). Before training, pitch rotation alone in complete darkness did not induce vergence eye movements in any of the monkeys tested. Vergence tracking without chair rotation showed decreased gain and increased phase lag (re vergence target velocity) at frequencies above 0.5 Hz. After training, the vergence response during chair rotation with the spot showed significantly higher gains and smaller phase lags at 0.3–1.0 Hz in all monkeys. Pitch rotation alone in complete darkness induced vergence eye movements with gains (eye vergence/chair) of 0.15–0.35 after training in two monkeys. These results suggest that vestibular information can be used effectively to modify vergence tracking.     

Neuronal activity in medial superior temporal area (MST) during memory-based smooth pursuit eye movements in monkeys

We examined recently neuronal substrates for predictive pursuit using a memory-based smooth pursuit task that distinguishes the discharge related to memory of visual motion-direction from that related to movement preparation. We found that the supplementary eye fields (SEF) contain separate signals coding memory and assessment of visual motion-direction, decision not-to-pursue, and preparation for pursuit. Since medial superior temporal area (MST) is essential for visual motion processing and projects to SEF, we examined whether MST carried similar signals. We analyzed the discharge of 108 MSTd neurons responding to visual motion stimuli. The majority (69/108 = 64%) were also modulated during smooth pursuit. However, in nearly all (104/108 = 96%) of the MSTd neurons tested, there was no significant discharge modulation during the delay periods that required memory of visual motion-direction or preparation for smooth pursuit or not-to-pursue. Only 4 neurons of the 108 (4%) exhibited significantly higher discharge rates during the delay periods; however, their responses were non-directional and not instruction specific. Representative signals in the MSTd clearly differed from those in the SEF during memory-based smooth pursuit. MSTd neurons are unlikely to provide signals for memory of visual motion-direction or preparation for smooth pursuit eye movements.     

Effect of phenibut and its composition with nicotinic acid on hemostasis in rats with brain ischemia

It is shown that, in rats with global cerebral ischemia modeled by a complete irreversible occlusion of the common carotid artery and forced hypotension, the hemostasis is characterized by a shift toward hypercoagulation. A single preventive introduction of phenibut and, to a greater degree, a composition of phenibut with nicotinic acid, in rats with acute cerebral ischemia reduced the extent of disturbances in the hemostasis system of experimental animals.     

HPLC Determination of Rhamnocitrin in Common Horse Chestnut (Aesculus hippocastanum L.) Buds

Pharmaceutical Chemistry Journal - An HPLC method for quantitative determination of rhamnocitrin in common horse chestnut (Aesculus hippocastanum L.) buds was developed. The rhamnocitrin content in...     

Comparative studies of the total flavonoids and anthracene derivatives contents of St. John's wort preparations

A comparative study of water-alcohol preparations of St. John's wort and imported medicinal formulations containing dry St. John's wort extract, Deprim, Negrustin, and Helarium Hypericum, was performed. The total flavonoids and athracene derivatives contents were significantly different in different medicinal formulations, though the ratios between them were essentially stable (at about 30:1), with the exception of St. John's wort infusion prepared using 40% ethanol. In the case of the preparation “St. John's Wort Infusion,” the greatest levels of biologically active compounds, particularly anthracene derivatives, were obtained by extraction with 70% ethanol. These studies provide evidence that Russian antidepressant medicinal formulations with chemical compositions similar to those of foreign St. John's wort preparations can be made. It is suggested that medicinal formulations based on St. John's wort be standardized in relation to the total flavonoids (in terms of rutin) and total anthracene derivatives (in terms of hypericin) contents. Translated from Khimiko-Farmatsevticheskii Zhurnal, Vol. 42, No. 10, pp. 39–42, October, 2008.     

Activity of pursuit neurons in the caudal part of the frontal eye fields during static roll-tilt

The smooth-pursuit system and vestibular system interact to keep the retinal target image on the fovea during head and/or whole body movements. The caudal part of the frontal eye fields (FEF) in the fundus of arcuate sulcus contains pursuit neurons and the majority of them respond to vestibular stimulation induced by whole-body rotation, that activates primarily semi-circular canals, and by whole-body translation, that activates otoliths. To examine whether coordinate frames representing FEF pursuit signals are orbital or earth-vertical, we compared preferred directions during upright and static, whole-body roll-tilt in head- and trunk-restrained monkeys. Preferred directions (re monkeys’ head/trunk axis) of virtually all pursuit neurons tested (n = 21) were similar during upright and static whole-body roll-tilt. The slight shift of preferred directions of the majority of neurons could be accounted for by ocular counter-rolling. The mean (±SD) differences in preferred directions between upright and 40° right ear down and between upright and 40° left ear down were 6° (±6°) and 5° (±5°), respectively. Visual motion preferred directions were also similar in five pursuit neurons tested. To examine whether FEF pursuit neurons could signal static whole-body roll-tilt, we compared mean discharge rates of 29 neurons during fixation of a stationary spot while upright and during static, whole-body roll-tilt. Virtually all neurons tested (28/29) did not exhibit a significant difference in mean discharge rates between the two conditions. These results suggest that FEF pursuit neurons do not signal static roll-tilt and that they code pursuit signals in head/trunk-centered coordinates.     

Neuronal activity in the caudal frontal eye fields of monkeys during memory-based smooth pursuit eye movements: comparison with the supplementary eye fields

Recently, we examined the neuronal substrate of predictive pursuit during memory-based smooth pursuit and found that supplementary eye fields (SEFs) contain signals coding assessment and memory of visual motion direction, decision not-to-pursue ("no-go"), and preparation for pursuit. To determine whether these signals were unique to the SEF, we examined the discharge of 185 task-related neurons in the caudal frontal eye fields (FEFs) in 2 macaques. Visual motion memory and no-go signals were also present in the caudal FEF but compared with those in the SEF, the percentage of neurons coding these signals was significantly lower. In particular, unlike SEF neurons, directional visual motion responses of caudal FEF neurons decayed exponentially. In contrast, the percentage of neurons coding directional pursuit eye movements was significantly higher in the caudal FEF than in the SEF. Unlike SEF inactivation, muscimol injection into the caudal FEF did not induce direction errors or no-go errors but decreased eye velocity during pursuit causing an inability to compensate for the response delays during sinusoidal pursuit. These results indicate significant differences between the 2 regions in the signals represented and in the effects of chemical inactivation suggesting that the caudal FEF is primarily involved in generating motor commands for smooth-pursuit eye movements.     

Otolith inputs to pursuit neurons in the frontal eye fields of alert monkeys

The smooth-pursuit system must interact with the vestibular system to maintain the accuracy of eye movements in space during head movement. Maintenance of a target image on the foveae is required not only during head rotation which activates primarily semi-circular canals but also during head translation which activates otolith organs. The caudal part of the frontal eye fields (FEF) contains pursuit neurons. The majority of them receive vestibular inputs induced by whole body rotation. However, it has not been tested whether FEF pursuit neurons receive otolith inputs. In the present study, we first classified FEF pursuit neurons as belonging to one of three groups (vergence + fronto-parallel pursuit, vergence only, fronto-parallel pursuit only) based on their responses during fronto-parallel pursuit and mid-sagittal vergence-pursuit. We, then, tested discharge modulation of these neurons during fore/aft and/or right/left translation by passively moving the whole body sinusoidally at 0.33 Hz (±10 cm, peak velocity 19 cm/s; 0.04g). The majority of FEF pursuit neurons in all three groups were activated by fore/aft and right/left translation without a target in complete darkness. There was no correlation between the magnitude of discharge modulation and translational vestibulo-ocular reflex (VOR). Preferred directions of translational responses were distributed nearly evenly in front of the monkeys. Discharge modulation was also observed when a target moved together with whole body, requiring the monkeys to cancel the translational VOR. These results indicate that the discharge modulation of FEF pursuit neurons during whole body translation reflected otolith inputs.