Search

Your search keyword '"Frens, M.A."' showing total 162 results
Start Over Author "Frens, M.A."
162 results on '"Frens, M.A."'

1. Learning to stand with sensorimotor delays generalizes across directions and from hand to leg effectors

Author

Rasman, B.G., Blouin, J.S., Nasrabadi, A.M., Woerkom, R. van, Frens, M.A., Forbes, P.A., Rasman, B.G., Blouin, J.S., Nasrabadi, A.M., Woerkom, R. van, Frens, M.A., and Forbes, P.A.

Abstract

Contains fulltext : 304975.pdf (Publisher’s version ) (Open Access), Humans receive sensory information from the past, requiring the brain to overcome delays to perform daily motor skills such as standing upright. Because delays vary throughout the body and change over a lifetime, it would be advantageous to generalize learned control policies of balancing with delays across contexts. However, not all forms of learning generalize. Here, we use a robotic simulator to impose delays into human balance. When delays are imposed in one direction of standing, participants are initially unstable but relearn to balance by reducing the variability of their motor actions and transfer balance improvements to untrained directions. Upon returning to normal standing, aftereffects from learning are observed as small oscillations in control, yet they do not destabilize balance. Remarkably, when participants train to balance with delays using their hand, learning transfers to standing with the legs. Our findings establish that humans use experience to broadly update their neural control to balance with delays., 20 p.

Published
2024

3. No effect of anodal tDCS on motor cortical excitability and no evidence for responders in a large double-blind placebo-controlled trial

Author

Jonker, Z.D. (Zeb D.), Gaiser, C. (Carolin), Tulen, J.H.M. (Joke), Ribbers, G.M. (Gerard), Frens, M.A. (Maarten), Selles, R.W. (Ruud), Jonker, Z.D. (Zeb D.), Gaiser, C. (Carolin), Tulen, J.H.M. (Joke), Ribbers, G.M. (Gerard), Frens, M.A. (Maarten), and Selles, R.W. (Ruud)

Abstract

Background: Transcranial direct current stimulation (tDCS) has emerged as a non-invasive brain stimulation technique. Most studies show that anodal tDCS increases cortical excitability. However, this effect has been found to be highly variable. Objective: To test the effect of anodal tDCS on cortical excitability and the interaction effect of two participant-specific factors that may explain individual differences in sensitivity to anodal tDCS: the Brain Derived Neurotrophic Factor Val66Met polymorphism (BDNF genotype) and the latency difference between anterior-posterior and lateromedial TMS pulses (APLM latency). Methods: In 62 healthy participants, cortical excitability over the left motor cortex was measured before and after anodal tDCS at 2 mA for 20 min in a pre-registered, double-blind, randomized, placebo-controlled trial with repeated measures. Results: We did not find a main effect of anodal tDCS, nor an interaction effect of the participant-specific predictors. Moreover, further analyses did not provide evidence for the existence of responders and non-responders. Conclusion: This study indicates that anodal tDCS at 2 mA for 20 min may not reliably affect cortical excitability.

Published
2021
Full Text
View/download PDF

4. The effects of pause software on the temporal characteristics of computer use

Author

Slijper, H.P., Richter, J.M., Smeets, J.B.J., and Frens, M.A.

Subjects
User groups -- Physiological aspects, User groups -- Health aspects, User group, Architecture and design industries, Business
Abstract

The work-pause pattern of computer users was investigated and the effects of imposing pause regimes on such patters were studied. It was observed that the introduction of short duration pauses by commercially available pause software did not materially affect the outcome.

Published
2007

5. A Neuroanatomically Grounded Optimal Control Model of the Compensatory Eye Movement System in Mice

Author

Holland, P.J. (Peter), Sibindi, T.M. (Tafadzwa), Ginzburg, M. (Marik), Das, S. (Suman), Arkesteijn, K. (Kiki), Frens, M.A. (Maarten), Donchin, O. (Opher), Holland, P.J. (Peter), Sibindi, T.M. (Tafadzwa), Ginzburg, M. (Marik), Das, S. (Suman), Arkesteijn, K. (Kiki), Frens, M.A. (Maarten), and Donchin, O. (Opher)

Abstract

We present a working model of the compensatory eye movement system in mice. We challenge the model with a data set of eye movements in mice (n =34) recorded in 4 different sinusoidal stimulus conditions with 36 different combinations of frequency (0.1–3.2 Hz) and amplitude (0.5–8°) in each condition. The conditions included vestibular stimulation in the dark (vestibular-ocular reflex, VOR), optokinetic stimulation (optokinetic reflex, OKR), and two combined visual/vestibular conditions (the visual-vestibular ocular reflex, vVOR, and visual suppression of the VOR, sVOR). The model successfully reproduced the eye movements in all conditions, except for minor failures to predict phase when gain was very low. Most importantly, it could explain the interaction of VOR and OKR when the two reflexes are activated simultaneously during vVOR stimulation. In addition to our own data, we also reproduced the behavior of the compensatory eye movement system found in the existing literature. These include its response to sum-of-sines stimuli, its response after lesions of the nucleus prepositus hypoglossi or the flocculus, characteristics of VOR adaptation, and characteristics of drift in the dark. Our model is based on ideas of state prediction and forward modeling that have been widely used in the study of motor control. However, it represents one of the first quantitative efforts to simulate the full range of behaviors of a specific system. The model has two separate processing loops, one for vestibular stimulation and one for visual stimulation. Importantly, state prediction in the visual processing loop depends on a forward model of residual reti

Published
2020
Full Text
View/download PDF

10. Developmental changes in visual search are determined by changing visuospatial abilities and task repetition: a longitudinal study in adolescents

Author

Burggraaf, R. (Rudolf), Geest, J.N. (Jos) van der, Hooge, I.Th.C. (Ignace), Frens, M.A. (Maarten), Burggraaf, R. (Rudolf), Geest, J.N. (Jos) van der, Hooge, I.Th.C. (Ignace), and Frens, M.A. (Maarten)

Abstract

Using a longitudinal study design, a group of 94 adolescents participated in a visual search task and a visuospatial ability task yearly for four consecutive years. We analyzed the association between changes in visuospatial ability and changes in visual search performance and behavior and estimated additional effects of age and task repetition. Visuospatial ability was measured with the Design Organization Test (DOT). Search performance was analyzed in terms of reaction time and response accuracy. Search behavior was analyzed in terms of the number of fixations per trial, the saccade amplitude, and the distribution of fixations over different types of elements. We found that both the increase in age and the yearly repetition of the DOT had a positive effect on visuospatial ability. We show that the acceleration of visual search during childhood can be explained by the increase in visuospatial abilities with age during adolescence. With the yearly task repetition, visual search became faster and more accurate, while fewer fixations were made with larger saccade amplitudes. The combination of increasing visuospatial ability and task repetition makes visual search more effective and might increase the performance of many daily tasks during adolescence.

Published
2019
Full Text
View/download PDF

11. The Vestibular Drive for Balance Control Is Dependent on Multiple Sensory Cues of Gravity

Author

Arntz, A.I., van der Putte, D.A.M., Jonker, Z.D., Hauwert, C.M., Frens, M.A. (Maarten), Forbes, P.A., Arntz, A.I., van der Putte, D.A.M., Jonker, Z.D., Hauwert, C.M., Frens, M.A. (Maarten), and Forbes, P.A.

Abstract

Vestibular signals, which encode head movement in space as well as orientation relative to gravity, contribute to the ongoing muscle activity required to stand. The strength of this vestibular contribution changes with the presence and quality of sensory cues of balance. Here we investigate whether the vestibular drive for standing balance also depends on different sensory cues of gravity by examining vestibular-evoked muscle responses when independently varying load and gravity conditions. Standing subjects were braced by a backboard structure that limited whole-body sway to the sagittal plane while load and vestibular cues of gravity were manipulated by: (a) loading the body downward at 1.5 and 2 times body weight (i.e., load cues), and/or (b) exposing subjects to brief periods (20 s) of micro- (<0.05 g) and hyper-gravity (∼1.8 g) during parabolic flights (i.e., vestibular cues). A stochastic electrical vestibular stimulus (0–25 Hz) delivered during these tasks evoked a vestibular-error signal and corrective muscles responses that were used to assess the vestibular drive to standing balance. With additional load, the magnitude of the vestibular-evoked muscle responses progressively increased, however, when these responses were normalized by the ongoing muscle activity, they decreased and plateaued at 1.5 times body weight. This demonstrates that the increased muscle activity necessary to stand with additional load is accompanied a proportionally smaller increase in vestibular input. This reduction in the relative vestibular contribution to balance was also observed when we varied the vestibular cues of gravity, but only during an absence (<0.05 g) and not an excess (∼1.8 g) of gravity when compared to conditions with normal 1 g gravity signals and equivalent load signals. Despite these changes, vestibular-evoked responses were observed in all conditions, indicating that vestibular cues of balance contribute to upright standing even in the near absence of a vestibu

Published
2019
Full Text
View/download PDF

15. TMS motor mapping: Comparing the absolute reliability of digital reconstruction methods to the golden standard

Author

Jonker, Z.D. (Zeb D.), Vliet, R. (Rick) van der, Hauwert, C.M. (Christopher M.), Gaiser, C. (Carolin), Tulen, J.H.M. (Joke), Geest, J.N. (Jos) van der, Donchin, O. (Opher), Ribbers, G.M. (Gerard), Frens, M.A. (Maarten), Selles, R.W. (Ruud), Jonker, Z.D. (Zeb D.), Vliet, R. (Rick) van der, Hauwert, C.M. (Christopher M.), Gaiser, C. (Carolin), Tulen, J.H.M. (Joke), Geest, J.N. (Jos) van der, Donchin, O. (Opher), Ribbers, G.M. (Gerard), Frens, M.A. (Maarten), and Selles, R.W. (Ruud)

Abstract

Background: Changes in transcranial magnetic stimulation motor map parameters can be used to quantify plasticity in the human motor cortex. The golden standard uses a counting analysis of motor evoked potentials (MEPs) acquired with a predefined grid. Recently, digital reconstruction methods have been proposed, allowing MEPs to be acquired with a faster pseudorandom procedure. However, the reliability of these reconstruction methods has never been compared to the golden standard. Objective: To compare the absolute reliability of the reconstruction methods with the golden standard. Methods: In 21 healthy subjects, both grid and pseudorandom acquisition were performed twice on the first day and once on the second day. The standard error of measurement was calculated for the counting analysis and the digital reconstructions. Results: The standard error of measurement was at least equal using digital reconstructions. Conclusion: Pseudorandom acquisition and digital reconstruction can be used in intervention studies without sacrificing reliability.

Published
2018
Full Text
View/download PDF

16. Visual search accelerates during adolescence

Author

Burggraaf, R. (Rudolf), Geest, J.N. (Jos) van der, Frens, M.A. (Maarten), Hooge, I.Th.C. (Ignace), Burggraaf, R. (Rudolf), Geest, J.N. (Jos) van der, Frens, M.A. (Maarten), and Hooge, I.Th.C. (Ignace)

Abstract

We studied changes in visual-search performance and behavior during adolescence. Search performance was analyzed in terms of reaction time and response accuracy. Search behavior was analyzed in terms of the objects fixated and the duration of these fixations. A large group of adolescents (N = 140; age: 12-19 years; 47% female, 53% male) participated in a visual-search experiment in which their eye movements were recorded with an eye tracker. The experiment consisted of 144 trials (50% with a target present), and participants had to decide whether a target was present. Each trial showed a search display with 36 Gabor patches placed on a hexagonal grid. The target was a vertically oriented element with a high spatial frequency. Nontargets differed from the target in spatial frequency, orientation, or both. Search performance and behavior changed during adolescence; with increasing age, fixation duration and reaction time decreased. Response accuracy, number of fixations, and selection of elements to fixate upon did not change with age. Thus, the speed of foveal discrimination increases with age, while the efficiency of peripheral selection does not change. We conclude that the way visual information is gathered does not change during adolescence, but the processing of visual information becomes faster.

Published
2018
Full Text
View/download PDF

17. The influence of cervical movement on eye stabilization reflexes

Author

Castelijns Ischebeck, B.K. (Britta), Vries, J. (Jurryt) de, Wingerden, J-P. (Jean-Paul) van, Kleinrensink, G.J. (Gert Jan), Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Castelijns Ischebeck, B.K. (Britta), Vries, J. (Jurryt) de, Wingerden, J-P. (Jean-Paul) van, Kleinrensink, G.J. (Gert Jan), Frens, M.A. (Maarten), and Geest, J.N. (Jos) van der

Abstract

To investigate the influence of the amount of cervical movement on the cervico-ocular reflex (COR) and vestibulo-ocular reflex (VOR) in healthy individuals. Eye stabilization reflexes, especially the COR, are changed in neck pain patients. In healthy humans, the strength of the VOR and the COR are inversely related. In a cross-over trial the amplitude of the COR and VOR (measured with a rotational chair with eye tracking device) and the active cervical range of motion (CROM) was measured in 20 healthy participants (mean age 24.7). The parameters were tested before and after two different interventions (hyperkinesia: 20 min of extensive active neck movement; and hypokinesia: 60 min of wearing a stiff neck collar). In an additional replication experiment the

Published
2018
Full Text
View/download PDF

18. Cerebellar transcranial direct current stimulation interacts with BDNF Val66Met in motor learning

Author

Vliet, R. (Rick) van der, Jonker, Z.D. (Zeb D.), Louwen, S.C. (Suzanne C.), Heuvelman, M. (Marco), de Vreede, L. (Linda), Ribbers, G.M. (Gerard), Zeeuw, C.I. (Chris) de, Donchin, O. (Opher), Selles, R.W. (Ruud), Geest, J.N. (Jos) van der, Frens, M.A. (Maarten), Vliet, R. (Rick) van der, Jonker, Z.D. (Zeb D.), Louwen, S.C. (Suzanne C.), Heuvelman, M. (Marco), de Vreede, L. (Linda), Ribbers, G.M. (Gerard), Zeeuw, C.I. (Chris) de, Donchin, O. (Opher), Selles, R.W. (Ruud), Geest, J.N. (Jos) van der, and Frens, M.A. (Maarten)

Abstract

Background: Cerebellar transcranial direct current stimulation has been reported to enhance motor associative learning and motor adaptation, holding promise for clinical application in patients with movement disorders. However, behavioral benefits from cerebellar tDCS have been inconsistent. Objective: Identifying determinants of treatment success is necessary. BDNF Val66Met is a candidate determinant, because the polymorphism is associated with motor skill learning and BDNF is thought to mediate tDCS effects. Methods: We undertook two cerebellar tDCS studies in subjects genotyped for BDNF Val66Met. Subjects performed an eyeblink conditioning task and received sham, anodal or cathodal tDCS (N = 117, between-subjects design) or a vestibulo-ocular reflex adaptation task and received sham and anodal tDCS (N = 51 subjects, within-subjects design). Performance was quantified as a learning parameter from 0 to 100%. We investigated (1) the distribution of the learning parameter with mixture modeling presented as the mean (M), standard deviation (S) and proportion (P) of the groups, and (2) the role of BDNF Val66Met and cerebellar tDCS using linear regression presented as the regression coefficients (B) and odds ratios (OR) with equally-tailed intervals (ETIs). Results: For the eyeblink conditioning task, we found distinct groups of learners (MLearner = 67.2%; SLearner = 14.7%; PLearner = 61.6%) and non-learners (MNon-learner = 14.2%; SNon-learner = 8.0%; PNon-learner = 38.4%). Carriers of the BDNF Val66Met polymorphism were more likely to be learners (OR = 2.7 [1.2 6.2]). Within the group of learners, anodal tDCS supported eyeblink conditioning in BDNF Val66Met non-carriers (B = 11.9% 95%ETI = [0.8 23.0]%), but not in carriers (B = 1.0% 95%ETI = [-10.2 12.1]%). For the vestibulo-ocular reflex adaptation task, we found no effect of BDNF Val66Met (B = −2.0% 95%ETI = [-8.7 4.7]%) or anodal tDCS in either carriers (B = 3.4% 95%ETI = [-3.2 9.5]%) or non-carriers (B = 0.6% 95%ET

Published
2018
Full Text
View/download PDF

19. Cerebellar Cathodal Transcranial Direct Stimulation and Performance on a Verb Generation Task: A Replication Study

Author

Spielmann, K., Van Der Vliet, R., Sandt-Koenderman, W.M.E. (Mieke) van de, Frens, M.A. (Maarten), Ribbers, G.M. (Gerard), Selles, R.W., Van Vugt, S., Geest, J.N. (Jos) van der, Holland, P.J. (Peter), Spielmann, K., Van Der Vliet, R., Sandt-Koenderman, W.M.E. (Mieke) van de, Frens, M.A. (Maarten), Ribbers, G.M. (Gerard), Selles, R.W., Van Vugt, S., Geest, J.N. (Jos) van der, and Holland, P.J. (Peter)

Abstract

The role of the cerebellum in cognitive processing is increasingly recognized but still poorly understood. A recent study in this field applied cerebellar Transcranial Direct Current Stimulation (c-tDCS) to the right cerebellum to investigate the role of prefrontal-cerebellar loops in language aspects of cognition. Results showed that the improvement in participants' verbal response times on a verb generation task was facilitated immediately after cathodal c-tDCS, compared to anodal or sham c-tDCS. The primary aim of the present study is to replicate these findings and additionally to investigate possible longer term effects. A crossover within-subject design was used, comparing cathodal and sham c-tDCS. The experiment consisted of two visits with an interval of one week. Our results show no direct contribution of cathodal c-tDCS over the cerebellum to language task performance. However, one week later, the group receiving cathodal c-tDCS in the first visit show less improvement and increased variability in their verbal response times during the second visit, compared to the group receiving sham c-tDCS in the first visit. These findings suggest a potential negative effect of c-tDCS and warrant further investigation into long term effects of c-tDCS before undertaking clinical studies with poststroke patients with aphasia.

Published
2017
Full Text
View/download PDF

20. Performance on tasks of visuospatial memory and ability: A cross-sectional study in 330 adolescents aged 11 to 20

Author

Burggraaf, R. (Rudolf), Frens, M.A. (Maarten), Hooge, I.Th.C. (Ignace), Geest, J.N. (Jos) van der, Burggraaf, R. (Rudolf), Frens, M.A. (Maarten), Hooge, I.Th.C. (Ignace), and Geest, J.N. (Jos) van der

Abstract

Cognitive functions mature at different points in time between birth and adulthood. Of these functions, visuospatial skills, such as spatial memory and part-to-whole organization, have often been tested in children and adults but have been less frequently evaluated during adolescence. We studied visuospatial memory and ability during this critical developmental period, as well as the correlation between these abilities, in a large group of 330 participants (aged 11 to 20 years

Published
2017
Full Text
View/download PDF

21. Cerebellar tDCS does not enhance performance in an implicit categorization learning task

Author

Verhage, M.C. (Claire), Avila, E. (Eric), Frens, M.A. (Maarten), Donchin, O. (Opher), Geest, J.N. (Jos) van der, Verhage, M.C. (Claire), Avila, E. (Eric), Frens, M.A. (Maarten), Donchin, O. (Opher), and Geest, J.N. (Jos) van der

Abstract

Background: Transcranial Direct Current Stimulation (tDCS) is a form of non-invasive electrical stimulation that changes neuronal excitability in a polarity and site-specific manner. In cognitive tasks related to prefrontal and cerebellar learning, cortical tDCS arguably facilitates learning, but the few studies investigating cerebellar tDCS, however, are inconsistent. Objective: We investigate the effect of cerebellar tDCS on performance of an implicit categorization learning task. Methods: Forty participants performed a computerized version of an implicit categorization learning task where squares had to be sorted into two categories, according to an unknown but fixed rule that integrated both the size and luminance of the square. Participants did one round of categorization to familiarize themselves with the task and to provide a baseline of performance. After that, 20 participants received anodal tDCS (20 min, 1.5 mA) over the right cerebellum, and 19 participants received sham stimulation and simultaneously started a second session of the categorization task using a new rule. Results: As expected, subjects performed better in the second session than in the first, baseline session, showing increased accuracy scores and reduced reaction times. Over trials, participants learned the categorization rule, improving their accuracy and reaction times. However, we observed no effect of anodal tDCS stimulation on overall performance or on learning, compared to sham stimulation. Conclusion: These results suggest that cerebellar tDCS does not modulate performance and learning on an implicit categorization task.

Published
2017
Full Text
View/download PDF

22. Participation in a scientific pre-university program and medical students' interest in an academic career

Author

De Leng, W.E. (Wendy E.), Stegers-Jager, K.M. (Karen), Born, M.Ph. (Marise), Frens, M.A. (Maarten A.), Themmen, A.P.N. (Axel), De Leng, W.E. (Wendy E.), Stegers-Jager, K.M. (Karen), Born, M.Ph. (Marise), Frens, M.A. (Maarten A.), and Themmen, A.P.N. (Axel)

Abstract

Background: The proportion of medical doctors involved in research activities is declining. Undergraduate medical research programs are positively associated with medical students' research interest. Scientific pre-university programs (SPUPs) outside the medical domain are also positively associated with research interest, but have not been related to the shortage of clinician-scientists. This study examined the effect of an SPUP on medical students' research interest. Methods: This study was conducted at a Dutch medical school. Medical students in all years who had participated in an SPUP and first-year master students who had not participated in an SPUP were invited to fill out an online survey on extracurricular activities and future career interests. SPUP participants were compared with three groups of non-participants: (i) an unmatched group, (ii) a group matched on gender and pre-university Grade Point Average (pu-GPA) and (iii) a group matched on gender and first-year GPA, one to five years after finishing the SPUP. Participants evaluated the SPUP through ratings of statements about the program. Results: Two-hundred forty medical students, including 71 SPUP participants responded to the survey. SPUP participants participated significantly more often in the Honors class (i.e., extracurricular educational program for high-performing students), gained significantly more often extracurricular research experience, enrolled significantly more often in the Research master (i.e., research training program parallel to the clinical master program) and obtained significantly more often a scholarship than unmatched non-SPUP participants. Using a non-SPUP group matched on gender and pu-GPA reduced the effect size of the significant differences in Honors class participation, Research master participation and scholarship obtainment. Using a non-SPUP group matched on gender and first-year GPA rendered the significant difference in Research master participation and scholarshi

Published
2017
Full Text
View/download PDF

24. Cerebellar tDCS does not improve performance in probabilistic classification learning

Author

Seyed Majidi, N., Verhage, M.C. (Claire), Donchin, O. (Opher), Holland, P.J. (Peter), Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Seyed Majidi, N., Verhage, M.C. (Claire), Donchin, O. (Opher), Holland, P.J. (Peter), Frens, M.A. (Maarten), and Geest, J.N. (Jos) van der

Abstract

In this study, the role of the cerebellum in a cognitive learning task using transcranial direct current stimulation (tDCS) was investigated. Using a weather prediction task, subjects had to learn the probabilistic associations between a stimulus (a combination of cards) and an outcome (sun or rain). This task is a variant of a probabilistic classification learning task, for which it has been reported that prefrontal tDCS enhances performance. Using a between-subject design, all 30 subjects learned to improve their performance with increasing accuracies and shortened response times over a series of 500 trials. Subjects also became more confident in their prediction during the experiment. However, no differences in performance and learning were observed between subjects receiving sham stimulation (n = 10) or anodal stimulation (2 mA for 20 min) over either the right cerebellum (n = 10) or the left prefrontal cortex (n = 10). This suggests that stimulating the brain with cerebellar tDCS does not readily influence probabilistic classification performances, probably due to the rather complex nature of this cognitive task.

Published
2016
Full Text
View/download PDF

25. Impact of transcranial direct current stimulation (tDCS) on neuronal functions

Author

Das, S. (Suman), Holland, P.J. (Peter), Frens, M.A. (Maarten), Donchin, O. (Opher), Das, S. (Suman), Holland, P.J. (Peter), Frens, M.A. (Maarten), and Donchin, O. (Opher)

Abstract

Transcranial direct current stimulation (tDCS), a non-invasive brain stimulation technique, modulates neuronal excitability by the application of a small electrical current. The low cost and ease of the technique has driven interest in potential clinical applications. However, outcomes are highly sensitive to stimulation parameters, leading to difficulty maximizing the technique's effectiveness. Although reversing the polarity of stimulation often causes opposite effects, this is not always the case. Effective clinical application will require an understanding of how tDCS works; how it modulates a neuron; how it affects the local network; and how it alters inter-network signaling. We have summarized what is known regarding the mechanisms of tDCS from sub-cellular processing to circuit level communication with a particular focus on what can be learned from the polarity specificity of the effects.

Published
2016
Full Text
View/download PDF

27. Eye movements in patients with Whiplash Associated Disorders: A systematic review

Author

Castelijns Ischebeck, B.K. (Britta), Vries, J. (Jurryt) de, Geest, J.N. (Jos) van der, Janssen, M. (Malou), Wingerden, J-P. (Jean-Paul) van, Kleinrensink, G.J. (Gert Jan), Frens, M.A. (Maarten), Castelijns Ischebeck, B.K. (Britta), Vries, J. (Jurryt) de, Geest, J.N. (Jos) van der, Janssen, M. (Malou), Wingerden, J-P. (Jean-Paul) van, Kleinrensink, G.J. (Gert Jan), and Frens, M.A. (Maarten)

Abstract

Background: Many people with Whiplash Associated Disorders (WAD) report problems with vision, some of which may be due to impaired eye movements. Better understanding of such impaired eye movements could improve diagnostics and treatment strategies. This systematic review surveys the current evidence on changes in eye movements of patients with WAD and explains how the oculomotor system is tested. Methods: Nine electronic data bases were searched for relevant articles from inception until September 2015. All studies which investigated eye movements in patients with WAD and included a healthy control group were screened for inclusion. Qualifying studies were retrieved and independently assessed for methodological quality using the Methodology Checklists provided by the Scottish Intercollegiate Guidelines Network. Results: Fourteen studies out of 833 unique hits were included. Ten studies reported impaired eye movements in patients with WAD and in four studies no differences compared to healthy controls were found. Different methods of eye movement examination were used in the ten studies: in five studies, the smooth pursuit neck torsion test was positive, in two more the velocity and stability of head movements during eye-coordination tasks were decreased, and in another three studies the cervico-ocular reflex was elevated. Conclusions: Overall the reviewed studies show deficits in eye movement in patients with WAD, but studies and results are varied. When comparing the results of the 14 relevant publications, one should realise that there are significant differences in test set-up and patient population. In the majority of studies patients show altered compensatory eye movements and smooth pursuit movements which may impair the coordination of head and eyes.

Published
2016
Full Text
View/download PDF

28. Thinking in Possibilities: Unleashing creativity through assessment in a Problem-based learning environment in Liberal Arts and Sciences.

Author

Servant, V.F.C. (Virginie), Noordzij, G. (Gera), Spierenburg, E.J., Frens, M.A., Servant, V.F.C. (Virginie), Noordzij, G. (Gera), Spierenburg, E.J., and Frens, M.A.

Abstract

This paper addresses the way in which students’ cognitive creativity and the construction of meaning could be fostered by means of assessment in a Problem-based learning programme. We propose that a dual assessment structure within such a programme through examinations and coursework assignments could ensure the acquisition of a foundational knowledge base while allowing the development of the cognitive creati

Published
2015

29. Cerebellar tDCS does not affect performance in the N-back task

Author

Wessel, B.W. (Brenda) van, Verhage, M.C. (Claire), Holland, P.J. (Peter), Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Wessel, B.W. (Brenda) van, Verhage, M.C. (Claire), Holland, P.J. (Peter), Frens, M.A. (Maarten), and Geest, J.N. (Jos) van der

Abstract

The N-back task is widely used in cognitive research. Furthermore, the cerebellums role in cognitive processes is becoming more widely recognized. Studies using transcranial direct current stimulation (tDCS) have demonstrated effects of cerebellar stimulation on several cognitive tasks. Therefore, the aim of this study was to investigate the effects of cerebellar tDCS on cognitive performance by using the N-back task. The cerebellum of 12 participants was stimulated during the task. Moreover, the cognitive load was manipulated in N = 2, N = 3, and N = 4. Every participant received three tDCS conditions (anodal, cathodal, and sham) divided over three separated days. It was expected that anodal stimulation would improve performance on the task. Each participant performed 6 repetitions of every load in which correct responses, false alarms, and reaction times were recorded. We found significant differences between the three levels of load in the rate of correct responses and false alarms, indicating that subjects followed the expected pattern of performance for the N-back task. However, no significant differences between the three tDCS conditions were found. Therefore, it was concluded that in this study cognitive performance on the N-back task was not readily influenced by cerebellar tDCS, and any true effects are likely to be small. We discuss several limitations in task design and suggest future experiments to address such issues.

Published
2015
Full Text
View/download PDF

30. Single session imaging of cerebellum at 7 tesla: Obtaining structure and function of multiple motor subsystems in individual subjects

Author

Batson, M.A. (Melissa), Petridou, N. (Natalia), Klomp, D.W.J. (Dennis), Frens, M.A. (Maarten), Neggers, S.F.W. (Sebastiaan), Batson, M.A. (Melissa), Petridou, N. (Natalia), Klomp, D.W.J. (Dennis), Frens, M.A. (Maarten), and Neggers, S.F.W. (Sebastiaan)

Abstract

The recent increase in the use of high field MR systems is accompanied by a demand for acquisition techniques and coil systems that can take advantage of increased power and accuracy without being susceptible to increased noise. Physical location and anatomical complexity of targeted regions must be considered when attempting to image deeper structures with small nuclei and/or complex cytoarchitechtonics (i.e. small microvasculature and deep nuclei), such as the brainstem and the cerebellum (Cb). Once these obstacles are overcome, the concomitant increase in signal strength at higher field strength should allow for faster acquisition of MR images. Here we show that it is technically feasible to quickly and accurately detect blood oxygen level dependent (BOLD) signal changes and obtain anatomical images of Cb at high spatial resolutions in individual subjects at 7 Tesla in a single one-hour session. Images were obtained using two high-density multi-element surface coils (32 channels in total) placed beneath the head at the level of Cb, two channel transmission, and three-dimensional sensitivity encoded (3D, SENSE) acquisitions to investigate sensorimotor activations in Cb. Two classic sensorimotor tasks were used to detect Cb activations. BOLD signal changes during motor activity resulted in concentrated clusters of activity within the Cb lobules associated with each task, observed consistently and independently in each subject: Oculomotor vermis (VI/VII) and CrusI/II for pro- and anti-saccades; ipsilateral hemispheres IV-VI for finger tapping; and topographical separation of eye- and hand- activations in hemispheres VI and VIIb/VIII. Though fast temporal resolution was not attempted here, these functional patches of highly specific BOLD signal changes may reflect small-scale shunting of blood in the microvasculature of Cb. The observed improvements in acquisition time and signal detection are ideal for individualized investigations such as differentiation of functio

Published
2015
Full Text
View/download PDF

31. Cerebellar transcranial direct current stimulation effects on saccade adaptation

Author

Avila, E. (Eric), Geest, J.N. (Jos) van der, Kengne Kamga, S. (Sandra), Verhage, M.C. (Claire), Donchin, O. (Opher), Frens, M.A. (Maarten), Avila, E. (Eric), Geest, J.N. (Jos) van der, Kengne Kamga, S. (Sandra), Verhage, M.C. (Claire), Donchin, O. (Opher), and Frens, M.A. (Maarten)

Abstract

Saccade adaptation is a cerebellar-mediated type of motor learning in which the oculomotor system is exposed to repetitive errors. Different types of saccade adaptations are thought to involve distinct underlying cerebellar mechanisms. Transcranial direct current stimulation (tDCS) induces changes in neuronal excitability in a polarity-specific manner and offers a modulatory, noninvasive, functional insight into the learning aspects of different brain regions. We aimed to modulate the cerebellar influence on saccade gains during adaptation using tDCS. Subjects performed an inward (n = 10) or outward (n = 10) saccade adaptation experiment (25% intrasaccadic target step) while receiving 1.5 mA of anodal cerebellar tDCS delivered by a small contact electrode. Compared to sham stimulation, tDCS increased learning of saccadic inward adaptation but did not affect learning of outward adaptation. This may imply that plasticity mechanisms in the cerebellum are different between inward and outward adaptation. TDCS could have influenced specific cerebellar areas that contribute to inward but not outward adaptation. We conclude that tDCS can be used as a neuromodulatory technique to alter cerebellar oculomotor output, arguably by engaging wider cerebellar areas and increasing the available resources for learning.

Published
2015
Full Text
View/download PDF

32. Awareness of sensorimotor adaptation to visual rotations of different size

Author

Werner, S. (Susen), Van Aken, B.C. (Bernice C.), Hulst, T. (Thomas), Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Strüder, H.K. (Heiko K.), Donchin, O. (Opher), Werner, S. (Susen), Van Aken, B.C. (Bernice C.), Hulst, T. (Thomas), Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Strüder, H.K. (Heiko K.), and Donchin, O. (Opher)

Abstract

Previous studies on sensorimotor adaptation revealed no awareness of the nature of the perturbation after adaptation to an abrupt 30° rotation of visual feedback or after adaptation to gradually introduced perturbations. Whether the degree of awareness depends on the magnitude of the perturbation, though, has as yet not been tested. Instead of using questionnaires, as was often done in previous work, the present study used a process dissociation procedure to measure awareness and unawareness. A naïve, implicit group and a group of subjects using explicit strategies adapted to 20°, 40° and 60° cursor rotations in different adaptation blocks that were each followed by determination of awareness and unawareness indices. The awareness index differed between groups and increased from 20° to 60° adaptation. In contrast, there was no group difference for the unawareness index, but it also depended on the size of the rotation. Early adaptation varied between groups and correlated with awareness: The more awareness a participant had developed the more the person adapted in the beginning of the adaptation block. In addition, there was a significant group difference for savings but it did not correlate with awareness. Our findings suggest that awareness depends on perturbation size and that aware and strategic processes are differentially involved during adaptation and savings. Moreover, the use of the process dissociation procedure opens the opportunity to determine awareness and unawareness indices in future sensorimotor adaptation research.

Published
2015
Full Text
View/download PDF

33. Human gaze following response is affected by visual acuity

Author

Spoor, M. (Marcella), Hosseini, M. (Mehran), Alphen, B. (Bart) van, Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Spoor, M. (Marcella), Hosseini, M. (Mehran), Alphen, B. (Bart) van, Frens, M.A. (Maarten), and Geest, J.N. (Jos) van der

Abstract

The present study investigated how gaze following eye movements are affected by stimulus contrast and spatial frequency and by ab

Published
2014
Full Text
View/download PDF

34. Cerebellar motor learning deficits in medicated and medication-free men with recent-onset schizophrenia

Author

Coesmans, M.P.H. (Michiel), Röder, C. (Constantin), Smit, A.E. (Albertine Eline), Koekkoek, S.K.E. (Bas), Zeeuw, C.I. (Chris) de, Frens, M.A. (Maarten), Geest, J.N. (Jos) van der, Coesmans, M.P.H. (Michiel), Röder, C. (Constantin), Smit, A.E. (Albertine Eline), Koekkoek, S.K.E. (Bas), Zeeuw, C.I. (Chris) de, Frens, M.A. (Maarten), and Geest, J.N. (Jos) van der

Abstract

Background: The notion that cerebellar deficits may underlie clinical symptoms in people with schizophrenia is tested by evaluating 2 forms of cerebellar learning in patients with recent-onset schizophrenia. A potential medication effect is evaluated by including patients with or without antipsychotics. Methods: We assessed saccadic eye movement adaptation and eyeblink conditioning in men with recentonset schizophrenia who were taking antipsychotic medication or who were antipsychotic-free and in age-matched controls. Results: We included 39 men with schizophrenia (10 who were taking clozapine, 16 who were taking haloperidol and 13 who were antipsychoticfree) and 29 controls in our study. All participants showed significant saccadic

Published
2014
Full Text
View/download PDF

35. Vestibular role of KCNQ4 and KCNQ5 K+ channels revealed by mouse models

Author

Spitzmaul, G. (Guillermo), Tolosa, L. (Leonardo), Winkelman, B.H.J. (Beerend), Heidenreich, M. (Matthias), Frens, M.A. (Maarten), Chabbert, C. (Christian), Zeeuw, C.I. (Chris) de, Jentsch, T.J. (Thomas), Spitzmaul, G. (Guillermo), Tolosa, L. (Leonardo), Winkelman, B.H.J. (Beerend), Heidenreich, M. (Matthias), Frens, M.A. (Maarten), Chabbert, C. (Christian), Zeeuw, C.I. (Chris) de, and Jentsch, T.J. (Thomas)

Abstract

The function of sensory hair cells of the cochlea and vestibular organs depends on an influx of K+ through apical mechanosensitive ion channels and its subsequent removal over their basolateral membrane. The KCNQ4 (Kv7.4) K+ channel, which is mutated in DFNA2 human hearing loss, is expressed in the basal membrane of cochlear outer hair cells where it may mediate K+ efflux. Like the related K+ channel KCNQ5 (Kv7.5), KCNQ4 is also found at calyx terminals ensheathing type I vestibular hair cells where it may be localized pre- or postsynaptically. Making use of Kcnq4-/- mice lacking KCNQ4, as well as Kcnq4dn/dn and Kcnq5dn/dn mice expressing dominant negative channel mutants, we now show unambiguously that in adult mice both channels reside in postsynaptic calyx-forming neurons, but cannot be detected in the innervated hair cells. Accordingly, whole cell currents of vestibular hair cells did not differ between genotypes. Neither Kcnq4-/-, Kcnq5 dn/dn nor Kcnq4-/-/ Kcnq5dn/dn double mutant mice displayed circling behavior found with severe vestibular impairment. However, a milder form of vestibular dysfunction was apparent from altered vestibulo- ocular reflexes in Kcnq4-/-/Kcnq5dn/dn and Kcnq4-/- mice. The larger impact of KCNQ4 may result from its preferential expression in central zone

Published
2013
Full Text
View/download PDF

37. Can parallel processing and competitive inhibition explain the generation of saccades?

Author

Frens, M.A., Hooge, I.T.C., and Goossens, H.H.L.M.

Subjects
Eye -- Movements, Human information processing -- Models, Inhibition -- Physiological aspects, Perceptual-motor processes -- Models, Psychology and mental health
Abstract

The framework of Findlay & Walker's target article provides a first attempt to model the saccadic system at all levels. Their scheme is based on two main principles. These are 'parallel processing of saccade timing and metrics' and 'competitive inhibition through winner-take-all strategies.' In our opinion, however, both concepts are in their strictest sense at odds with the current knowledge of the saccadic system, and need to be refined to make the scheme more relevant.

Published
1999

38. Transcranial magnetic stimulation and motor plasticity in human lateral cerebellum: Dual effect on saccadic adaptation

Author

Panouillères, M., Neggers, S.F.W., Gutteling, T.P., Salemme, R., Stigchel, S. van der, Geest, J.N. van der, Frens, M.A., Pélisson, D., Panouillères, M., Neggers, S.F.W., Gutteling, T.P., Salemme, R., Stigchel, S. van der, Geest, J.N. van der, Frens, M.A., and Pélisson, D.

Abstract

Item does not contain fulltext, The cerebellum is a key area for movement control and sensory-motor plasticity. Its medial part is considered as the exclusive cerebellar center controlling the accuracy and adaptive calibration of saccadic eye movements. However, the contribution of other zones situated in its lateral part is unknown. We addressed this question in healthy adult volunteers by using magnetic resonance imaging (MRI)-guided transcranial magnetic stimulation (TMS). The double-step target paradigm was used to adaptively lengthen or shorten saccades. TMS pulses over the right hemisphere of the cerebellum were delivered at 0, 30, or 60 ms after saccade detection in separate recording sessions. The effects on saccadic adaptation were assessed relative to a fourth session where TMS was applied to Vertex as a control site. First, TMS applied upon saccade detection before the adaptation phase reduced saccade accuracy. Second, TMS applied during the adaptation phase had a dual effect on saccadic plasticity: adaptation after-effects revealed a potentiation of the adaptive lengthening and a depression of the adaptive shortening of saccades. For the first time, we demonstrate that TMS on lateral cerebellum can influence plasticity mechanisms underlying motor performance. These findings also provide the first evidence that the human cerebellar hemispheres are involved in the control of saccade accuracy and in saccadic adaptation, with possibly different neuronal populations concerned in adaptive lengthening and shortening. Overall, these results require a reappraisal of current models of cerebellar contribution to oculomotor plasticity.

Published
2012

39. Albino mice as an animal model for infantile nystagmus syndrome

Author

Traber, D.L. (Daniel), Chen, C.-C. (Chien-Cheng), Huang, Y.-Y. (Ying-Yu), Spoor, M. (Marcella), Roos, J. (Jeanine), Frens, M.A. (Maarten), Straumann, D. (Dominik), Grimm, C. (Christian), Traber, D.L. (Daniel), Chen, C.-C. (Chien-Cheng), Huang, Y.-Y. (Ying-Yu), Spoor, M. (Marcella), Roos, J. (Jeanine), Frens, M.A. (Maarten), Straumann, D. (Dominik), and Grimm, C. (Christian)

Abstract

PURPOSE. Individuals with oculocutaneous albinism are predisposed to visual system abnormalities affecting the retina and retinofugal projections, which may lead to reduced visual acuity and Infantile Nystagmus Syndrome (INS). Due to absence of an established mammalian animal model, mechanisms underlying INS remain elusive. In this study, we screened wild-type mice of varying pigmentation for ocular motor abnormalities in order to identify a possible mouse model for INS. METHODS. Three albino mouse strains (CD1, BALB/c, DBA/1), and two normally pigmented strains (129S6, C57BL/6) were screened using infrared oculography. Varying visual stimuli (black or white background, stationary pattern, optokinetic, i.e., horizontally rotating pattern) were displayed to the full (fVF) or anterior visual field (aVF) of the restrained mouse. RESULTS. We found spontaneous nystagmus, specifically jerks and oscillations, in albino mice under all experimental conditions. Median eye velocity was between 0.8 and 3.4 deg/s, depending on the strain. In contrast, the eyes in pigmented mice were nearly stable with a median absolute eye velocity of below 0.4 deg/s. In albino mice, fVF optokinetic stimuli elicited an optokinetic response (OKR) in the correct direction, albeit with superimposed oscillations. However, aVF optokinetic stimuli evoked reversed OKR in these strains, a well known feature of INS. CONCLUSIONS. Based on our results, we endorse the investigated albino mouse strains as new animal models for INS.

Published
2012
Full Text
View/download PDF

40. Three-dimensional optokinetic eye movements in the C57BL/6J mouse

Author

Alphen, B. (Bart) van, Winkelman, B.H.J. (Beerend), Frens, M.A. (Maarten), Alphen, B. (Bart) van, Winkelman, B.H.J. (Beerend), and Frens, M.A. (Maarten)

Abstract

PURPOSE. To study three-dimensional optokinetic eye movements of wild-type C57BL/6J mice, the most commonly used mouse in oculomotor physiology. Optokinetic eye movements are reflexive eye movements that use visual feedback to minimize image motion across the retina. These gaze-stabilizing reflexes are a prominent model system for studying motor control and learning. They are three dimensional and consist of a horizontal, vertical, and torsional component. METHODS. Eye movements were evoked by sinusoidally rotating a virtual sphere of equally spaced dots at six frequencies (0.1-1 Hz), with a fixed amplitude of 5°. Markers were applied to the mouse eye and video oculography was used to record its movements in three dimensions. In addition, marker tracking was compared with conventional pupil tracking of horizontal optokinetic eye movements. RESULTS. Gains recorded with marker and pupil tracking are not significantly different. Optokinetic eye movements in mice are equally well developed in all directions and have a uniform input- output relation for all stimuli, including stimuli that evoke purely torsional eye movements, with gains close to unity and minimal phase differences. CONCLUSIONS. Optokinetic eye movements of C57Bl6 mice largely compensate for image motion over the retina, regardless of stimulus orientation. All responses are frequency-velocity dependent: gains decrease and phase lags increase with increasing stimulus frequency. Mice show strong torsional responses, with high gains at low stimulus frequency.

Published
2010
Full Text
View/download PDF

41. Forward models and state estimation in compensatory eye movements

Author

Frens, M.A. (Maarten), Donchin, O. (Opher), Frens, M.A. (Maarten), and Donchin, O. (Opher)

Abstract

The compensatory eye movement (CEM) system maintains a stable retinal image, integrating information from different sensory modalities to compensate for head movements. Inspired by recent models of the physiology of limb movements, we suggest that CEM can be modeled as a control system with three essential building blocks: a forward model that predicts the effects of motor commands; a state estimator that integrates sensory feedback into this prediction; and, a feedback controller that translates a state estimate into motor commands. We propose a specific mapping of nuclei within the CEM system onto these control functions. Specifically, we suggest that the Flocculus is responsible for generating the forward model prediction and that the Vestibular Nuclei integrate sensory feedback to generate an estimate of current state. Finally, the brainstem motor nuclei - in the case of horizontal compensation this means the Abducens Nucleus and the Nucleus Prepositus Hypoglossi - implement a feedback controller, translating state into motor commands. While these efforts to understand the physiological control system as a feedback control system are in their infancy, there is the intriguing possibility that CEM and targeted voluntary movements use the same cerebellar circuitry in fundamentally different ways.

Published
2009
Full Text
View/download PDF

42. Cortical and cerebellar activation induced by reflexive and voluntary saccades

Author

Schraa-Tam, C.K.L. (Caroline), Broekhoven, P.C.A. (Flip) van, Geest, J.N. (Jos) van der, Frens, M.A. (Maarten), Smits, M. (Marion), Lugt, A. (Aad) van der, Schraa-Tam, C.K.L. (Caroline), Broekhoven, P.C.A. (Flip) van, Geest, J.N. (Jos) van der, Frens, M.A. (Maarten), Smits, M. (Marion), and Lugt, A. (Aad) van der

Abstract

Reflexive saccades are driven by visual stimulation whereas voluntary saccades require volitional control. Behavioral and lesional studies suggest that there are two separate mechanisms involved in the generation of these two types of saccades. This study investigated differences in cerebral and cerebellar activation between reflexive and self-paced voluntary saccadic eye movements using functional magnetic resonance imaging. In two experiments (whole brain and cerebellum) using the same paradigm, differences in brain activations induced by reflexive and self-paced voluntary saccades were assessed. Direct comparison of the activation patterns showed that the frontal eye fields, parietal eye field, the motion-sensitive area (MT/V5), the precuneus (V6), and the angular and the cingulate gyri were more activated in reflexive saccades than in voluntary saccades. No significant difference in activation was found in the cerebellum. Our results suggest that the alleged separate mechanisms for saccadic control of reflexive and self-paced voluntary are mainly observed in cerebral rather than cerebellar areas.

Published
2009
Full Text
View/download PDF

45. Interaction between ocular stabilization reflexes in patients with whiplash injury

Author

Montfoort, I. (Inger), Kelders, W.P.A. (Willem), Geest, J.N. (Jos) van der, Schipper, I.B. (Inger), Feenstra, L. (Louw), Zeeuw, C.I. (Chris) de, Frens, M.A. (Maarten), Montfoort, I. (Inger), Kelders, W.P.A. (Willem), Geest, J.N. (Jos) van der, Schipper, I.B. (Inger), Feenstra, L. (Louw), Zeeuw, C.I. (Chris) de, and Frens, M.A. (Maarten)

Abstract

PURPOSE. In the past few decades, the automobile has become an increasingly more popular means of transport, which has led to an increasing number of rear-end collisions and consequently has resulted in more patients with whiplash-associated disorders (WADs). Recently, it was found that the gain of one of the ocular stabilization reflexes - the cervico-ocular reflex (COR) - is elevated in patients with whiplash injury. The COR responds to proprioceptive signals from the neck and acts in conjunction with the vestibulo-ocular reflex (VOR) and the optokinetic reflex (OKR) to preserve stable vision on the retina during head motion. Therefore, an investigation was conducted to determine whether the reported elevation of the COR in WADs is accompanied by changes in VOR or OKR. METHODS. Eye movements of 13 patients and 18 age-matched healthy controls were recorded with an infrared eye-tracking device. RESULTS. Analysis confirmed a significant increase in COR gain in whiplash patients. Meanwhile the VOR and OKR gains remained the same. No correlation was found between the gains of the reflexes in individual patients. This is in contrast to earlier observations in elderly subjects and subjects with labyrinthine defects, who showed increases in COR gain and decreases in VOR gain. CONCLUSIONS. Impaired neck motion, altered proprioception of the neck, or disorganization in the process of VOR plasticity could explain the lack of change in VOR gain. Copyright

Published
2006
Full Text
View/download PDF

46. De grootsheid van de kleine hersenen

Author

Frens, M.A. (Maarten) and Frens, M.A. (Maarten)

Abstract

Rede, in verkorte vorm uitgesproken ter gelegenheid van het aanvaarden van de leerstoel Systeemfysiologie aan het Erasmus MC, faculteit van de Erasmus Universtiteit Rotterdam op 25 april 2006

Published
2006

47. Motor coding in floccular climbing fibers

Author

Winkelman, B.H.J. (Beerend), Frens, M.A. (Maarten), Winkelman, B.H.J. (Beerend), and Frens, M.A. (Maarten)

Abstract

The climbing fibers (CFs) that project from the dorsal cap of the inferior olive (IO) to the flocculus of the cerebellar cortex have been reported to be purely sensory, encoding "retinal slip." However, a clear oculomotor projection from the nucleus prepositus hypoglossi (NPH) to the IO has been shown. We therefore studied the sensorimotor information that is present in the CF signal. We presented rabbits with visual motion noise stimuli to break up the tight relation between instantaneous retinal slip and eye movement. Strikingly, the information about the motor behavior in the CF signal more than doubled that of the sensory component and was time-locked more tightly. The contribution of oculomotor signals was independently confirmed by analysis of spontaneous eye movements in the absence of visual input. The motor component of the CF code is essential to distinguish unexpected slip from self-generated slip, which is a prerequisite for proper oculomotor learning. Copyright

Published
2006
Full Text
View/download PDF

49. Increased noise level of purkinje cell activities minimizes impact of their modulation during sensorimotor control.

Author

Hoebeek, F.E., Stahl, J.S., Alphen, A.M. van, Schonewille, M., Luo, C., Rutteman, M., Maagdenberg, A.M.J.M. van den, Molenaar, P.C., Goossens, H.H.L.M., Frens, M.A., Zeeuw, C.I. de, Hoebeek, F.E., Stahl, J.S., Alphen, A.M. van, Schonewille, M., Luo, C., Rutteman, M., Maagdenberg, A.M.J.M. van den, Molenaar, P.C., Goossens, H.H.L.M., Frens, M.A., and Zeeuw, C.I. de

Abstract

Contains fulltext : 48072.pdf (publisher's version ) (Closed access), While firing rate is well established as a relevant parameter for encoding information exchanged between neurons, the significance of other parameters is more conjectural. Here, we show that regularity of neuronal spike activities affects sensorimotor processing in tottering mutants, which suffer from a mutation in P/Q-type voltage-gated calcium channels. While the modulation amplitude of the simple spike firing rate of their floccular Purkinje cells during optokinetic stimulation is indistinguishable from that of wild-types, the regularity of their firing is markedly disrupted. The gain and phase values of tottering's compensatory eye movements are indistinguishable from those of flocculectomized wild-types or from totterings with the flocculus treated with P/Q-type calcium channel blockers. Moreover, normal eye movements can be evoked in tottering when the flocculus is electrically stimulated with regular spike trains mimicking the firing pattern of normal simple spikes. This study demonstrates the importance of regularity of firing in Purkinje cells for neuronal information processing.

Published
2005

Catalog

Books, media, physical & digital resources
See catalog results