Your search keyword '"Schaffelhofer, Stefan"' showing total 7 results

1. A goal-driven modular neural network predicts parietofrontal neural dynamics during grasping.

Author

Michaels, Jonathan A., Schaffelhofer, Stefan, Agudelo-Toro, Andres, and Scherberger, Hansjörg

Subjects

*RECURRENT neural networks, *GOAL (Psychology), *PREMOTOR cortex, *MOTOR cortex, *MODULAR construction

Abstract

One of the primary ways we interact with the world is using our hands. In macaques, the circuit spanning the anterior intraparietal area, the hand area of the ventral premotor cortex, and the primary motor cortex is necessary for transforming visual information into grasping movements. However, no comprehensive model exists that links all steps of processing from vision to action. We hypothesized that a recurrent neural network mimicking the modular structure of the anatomical circuit and trained to use visual features of objects to generate the required muscle dynamics used by primates to grasp objects would give insight into the computations of the grasping circuit. Internal activity of modular networks trained with these constraints strongly resembled neural activity recorded from the grasping circuit during grasping and paralleled the similarities between brain regions. Network activity during the different phases of the task could be explained by linear dynamics for maintaining a distributed movement plan across the network in the absence of visual stimulus and then generating the required muscle kinematics based on these initial conditions in a module-specific way. These modular models also outperformed alternative models at explaining neural data, despite the absence of neural data during training, suggesting that the inputs, outputs, and architectural constraints imposed were sufficient for recapitulating processing in the grasping circuit. Finally, targeted lesioning of modules produced deficits similar to those observed in lesion studies of the grasping circuit, providing a potential model for how brain regions may coordinate during the visually guided grasping of objects. [ABSTRACT FROM AUTHOR]

Published

2020

2. Object vision to hand action in macaque parietal, premotor, and motor cortices.

Author

Schaffelhofer, Stefan and Scherberger, Hansjörg

Subjects

*PREMOTOR cortex, *VISUAL perception, *MACAQUE behavior, *PREHENSION (Physiology), *NEURAL circuitry

Abstract

Grasping requires translating object geometries into appropriate hand shapes. How the brain computes these transformations is currently unclear. We investigated three key areas of the macaque cortical grasping circuit with microelectrode arrays and found cooperative but anatomically separated visual and motor processes. The parietal area AIP operated primarily in a visual mode. Its neuronal population revealed a specialization for shape processing, even for abstract geometries, and processed object features ultimately important for grasping. Premotor area F5 acted as a hub that shared the visual coding of AIP only temporarily and switched to highly dominant motor signals towards movement planning and execution. We visualize these non-discrete premotor signals that drive the primary motor cortex M1 to reflect the movement of the grasping hand. Our results reveal visual and motor features encoded in the grasping circuit and their communication to achieve transformation for grasping. [ABSTRACT FROM AUTHOR]

Published

2016

3. Decoding a Wide Range of Hand Configurations from Macaque Motor, Premotor, and Parietal Cortices.

Author

Schaffelhofer, Stefan, Agudelo-Toro, Andres, and Scherberger, Hansjörg

Subjects

*RHESUS monkeys, *MOTOR ability, *PREMOTOR cortex, *PARIETAL lobe, *PREHENSION (Physiology), *PROSTHETICS, *BAYESIAN analysis

Abstract

Despite recent advances in decoding cortical activity for motor control, the development of hand prosthetics remains a major challenge. To reduce the complexity of such applications, higher cortical areas that also represent motor plans rather than just the individual movements might be advantageous. We investigated the decoding of many grip types using spiking activity from the anterior intraparietal (AIP), ventralpremotor(F5),andprimary motor (M1) cortices. Two rhesus monkeys weretrained to grasp 50 objects in a delayed task while hand kinematics and spiking activity from six implanted electrode arrays (total of 192 electrodes) were recorded. Offline, we determined 20 grip types from the kinematic data and decoded these hand configurations and the grasped objects with a simple Bayesian classifier. When decoding from AIP, F5, and M1 combined, the mean accuracy was 50% (using planning activity) and 62% (during motor execution) for predicting the 50 objects (chance level, 2%) and substantially larger when predicting the 20 grip types (planning, 74%; execution, 86%; chance level, 5%). When decoding from individual arrays, objects and grip types could be predicted well during movement planning from AIP (medial array) and F5 (lateral array), whereas M1 predictions were poor. In contrast, predictions during movement execution were best from M1, whereas F5 performed only slightly worse. These results demonstrate for the first time that a large number of grip types can be decoded from higher cortical areas during movement preparation and execution, which could be relevant for future neuroprosthetic devices that decode motor plans. [ABSTRACT FROM AUTHOR]

Published

2015

4. Information-processing dynamics in neural networks of macaque cerebral cortex reflect cognitive state and behavior.

Author

Varley, Thomas F., Sporns, Olaf, Schaffelhofer, Stefan, Scherberger, Hansjörg, and Dann, Benjamin

Subjects

*CEREBRAL cortex, *BIOLOGICAL neural networks, *MACAQUES, *INFORMATION processing

Abstract

One of the essential functions of biological neural networks is the processing of information. This includes everything from processing sensory information to perceive the environment, up to processing motor information to interact with the environment. Due to methodological limitations, it has been historically unclear how information processing changes during different cognitive or behavioral states and to what extent information is processed within or between the network of neurons in different brain areas. In this study, we leverage recent advances in the calculation of information dynamics to explore neural-level processing within and between the frontoparietal areas AIP, F5, and M1 during a delayed grasping task performed by three macaque monkeys. While information processing was high within all areas during all cognitive and behavioral states of the task, interareal processing varied widely: During visuomotor transformation, AIP and F5 formed a reciprocally connected processing unit, while no processing was present between areas during the memory period. Movement execution was processed globally across all areas with predominance of processing in the feedback direction. Furthermore, the fine-scale network structure reconfigured at the neuron level in response to different grasping conditions, despite no differences in the overall amount of information present. These results suggest that areas dynamically form higher-order processing units according to the cognitive or behavioral demand and that the information-processing network is hierarchically organized at the neuron level, with the coarse network structure determining the behavioral state and finer changes reflecting different conditions. [ABSTRACT FROM AUTHOR]

Published

2023

5. Using camera-guided electrode microdrive navigation for precise 3D targeting of macaque brain sites.

Author

Crayen, Max Arwed, Kagan, Igor, Esghaei, Moein, Hoehl, Dirk, Thomas, Uwe, Prückl, Robert, Schaffelhofer, Stefan, and Treue, Stefan

Subjects

*IRON ores, *MACAQUES, *NEUROPLASTICITY, *ELECTRODES, *INFRARED cameras, *DURA mater, *GLOBAL Positioning System

Abstract

Spatial accuracy in electrophysiological investigations is paramount, as precise localization and reliable access to specific brain regions help the advancement of our understanding of the brain's complex neural activity. Here, we introduce a novel, multi camera-based, frameless neuronavigation technique for precise, 3-dimensional electrode positioning in awake monkeys. The investigation of neural functions in awake primates often requires stable access to the brain with thin and delicate recording electrodes. This is usually realized by implanting a chronic recording chamber onto the skull of the animal that allows direct access to the dura. Most recording and positioning techniques utilize this implanted recording chamber as a holder of the microdrive or to hold a grid. This in turn reduces the degrees of freedom in positioning. To solve this problem, we require innovative, flexible, but precise tools for neuronal recordings. We instead mount the electrode microdrive above the animal on an arch, equipped with a series of translational and rotational micromanipulators, allowing movements in all axes. Here, the positioning is controlled by infrared cameras tracking the location of the microdrive and the monkey, allowing precise and flexible trajectories. To verify the accuracy of this technique, we created iron deposits in the tissue that could be detected by MRI. Our results demonstrate a remarkable precision with the confirmed physical location of these deposits averaging less than 0.5 mm from their planned position. Pilot electrophysiological recordings additionally demonstrate the accuracy and flexibility of this method. Our innovative approach could significantly enhance the accuracy and flexibility of neural recordings, potentially catalyzing further advancements in neuroscientific research. [ABSTRACT FROM AUTHOR]

Published

2024

6. Resting state functional connectivity patterns associated with pharmacological treatment resistance in temporal lobe epilepsy.

Author

Pressl, Christina, Brandner, Philip, Schaffelhofer, Stefan, Blackmon, Karen, Dugan, Patricia, Holmes, Manisha, Thesen, Thomas, Kuzniecky, Ruben, Devinsky, Orrin, and Freiwald, Winrich A.

Subjects

*TEMPORAL lobe epilepsy, *FUNCTIONAL magnetic resonance imaging, *MAGNETIC resonance imaging, *EPILEPSY, *PEOPLE with epilepsy

Abstract

Highlights • Resting State functional magnetic resonance imaging (Rs-fMRI) is utilized to visualize functional neuronal connectivity patterns. • In the past, Rs-fMRI techniques have been utilized to predict the lateralization of seizure foci in patients with temporal lobe epilepsy (TLE). • We asked whether associations between functional connectivity patterns and treatment response could be detected in TLE. • We find significant differences in thalamo-hippocampal functional connectivity between treatment-resistant and well-controlled TLE. • Aberrant functional connectivity patterns as measured by Rs-fMRI could thus serve as future biomarkers for treatment response in TLE. Abstract There are no functional imaging based biomarkers for pharmacological treatment response in temporal lobe epilepsy (TLE). In this study, we investigated whether there is an association between resting state functional brain connectivity (RsFC) and seizure control in TLE. We screened a large database containing resting state functional magnetic resonance imaging (Rs-fMRI) data from 286 epilepsy patients. Patient medical records were screened for seizure characterization, EEG reports for lateralization and location of seizure foci to establish uniformity of seizure localization within patient groups. Rs-fMRI data from patients with well-controlled left TLE, patients with treatment-resistant left TLE, and healthy controls were analyzed. Healthy controls and cTLE showed similar functional connectivity patterns, whereas trTLE exhibited a significant bilateral decrease in thalamo-hippocampal functional connectivity. This work is the first to demonstrate differences in neural network connectivity between well-controlled and treatment-resistant TLE. These differences are spatially highly focused and suggest sites for the etiology and possibly treatment of TLE. Altered thalamo-hippocampal RsFC thus is a potential new biomarker for TLE treatment resistance. [ABSTRACT FROM AUTHOR]

Published

2019

7. Uniting functional network topology and oscillations in the fronto-parietal single unit network of behaving primates.

Author

Dann, Benjamin, Michaels, Jonathan A., Schaffelhofer, Stefan, and Scherberger, Hansjörg

Subjects

*NEURAL circuitry, *PRIMATE behavior, *PARIETAL lobe, *NEURONS, *COGNITIVE ability

Abstract

The functional communication of neurons in cortical networks underlies higher cognitive processes. Yet, little is known about the organization of the single neuron network or its relationship to the synchronization processes that are essential for its formation. Here, we show that the functional single neuron network of three fronto-parietal areas during active behavior of macaque monkeys is highly complex. The network was closely connected (small-world) and consisted of functional modules spanning these areas. Surprisingly, the importance of different neurons to the network was highly heterogeneous with a small number of neurons contributing strongly to the network function (hubs), which were in turn strongly inter-connected (rich-club). Examination of the network synchronization revealed that the identified rich-club consisted of neurons that were synchronized in the beta or low frequency range, whereas other neurons were mostly non-oscillatory synchronized. Therefore, oscillatory synchrony may be a central communication mechanism for highly organized functional spiking networks. [ABSTRACT FROM AUTHOR]

Published

2016