Sensory Coding of Limb Kinematics in Motor Cortex across a Key Developmental Transition

Glanz, Ryan M.; Dooley, James C.; Sokoloff, Greta; Blumberg, Mark S.

doi:10.1523/jneurosci.0921-21.2021

Cited by 16 publications

(51 citation statements)

References 59 publications

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“…Twitching during early-life REM episodes, therefore, could facilitate the transformation of uncoordinated movements during infancy to the fine-tuned sensorimotor maps of an adult. Sensory feedback from twitching limbs are thought to contribute to motor learning and sensorimotor integration (Blumberg et al, 2013 , 2020 ; Sokoloff et al, 2015 ; Rio-Bermudez and Blumberg, 2018 ; Glanz et al, 2021 ), as reafference from myoclonic twitches selectively activates brain regions such as the thalamus, cortex, hippocampus, and cerebellum in infant rats (Khazipov et al, 2004 ; Mohns and Blumberg, 2010 ; Tiriac et al, 2012 ; Sokoloff et al, 2015 ). Because reafference signals from self-movement are gated during waking, sleep disruptions that interfere with twitching, and their corresponding neuronal activity may disrupt sensorimotor maturation (Tiriac and Blumberg, 2016 ).…”

Section: Developmentmentioning

confidence: 99%

Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Weiss

Donlea

2022

Front. Behav. Neurosci.

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Sleep is a vital physiological state that has been broadly conserved across the evolution of animal species. While the precise functions of sleep remain poorly understood, a large body of research has examined the negative consequences of sleep loss on neural and behavioral plasticity. While sleep disruption generally results in degraded neural plasticity and cognitive function, the impact of sleep loss can vary widely with age, between individuals, and across physiological contexts. Additionally, several recent studies indicate that sleep loss differentially impacts distinct neuronal populations within memory-encoding circuitry. These findings indicate that the negative consequences of sleep loss are not universally shared, and that identifying conditions that influence the resilience of an organism (or neuron type) to sleep loss might open future opportunities to examine sleep's core functions in the brain. Here, we discuss the functional roles for sleep in adaptive plasticity and review factors that can contribute to individual variations in sleep behavior and responses to sleep loss.

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Section: Developmentmentioning

confidence: 99%

Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Weiss

Donlea

2022

Front. Behav. Neurosci.

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“…Studies with kinematics coded with temporal basis functions have shown that a kinematic plan can be coded to reduce the bandwidth needed by a factor of ∼10 3 Hz (Iyer and Ballard, 2011;Won et al, 2020). More recently, sparse coding has been used to solve this problem (Glanz et al, 2021), despite unnecessary caution of its applicability to cortical motor areas (Beyeler et al, 2019). A tack that is still open would be our large sets of kinematic data to attempt to model cell responses 10 CMU Graphics Lab Motion Capture Database: http://mocap.cs.cmu.edu/ in cortical area M1 to see if they turn out to be correlated with Graziano's data.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Computational Modeling: Human Dynamic Model

2021

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Improvements in quantitative measurements of human physical activity are proving extraordinarily useful for studying the underlying musculoskeletal system. Dynamic models of human movement support clinical efforts to analyze, rehabilitate injuries. They are also used in biomechanics to understand and diagnose motor pathologies, find new motor strategies that decrease the risk of injury, and predict potential problems from a particular procedure. In addition, they provide valuable constraints for understanding neural circuits. This paper describes a physics-based movement analysis method for analyzing and simulating bipedal humanoid movements. The model includes the major body segments and joints to report human movements' energetic components. Its 48 degrees of freedom strike a balance between very detailed models that include muscle models and straightforward two-dimensional models. It has sufficient accuracy to analyze and synthesize movements captured in real-time interactive applications, such as psychophysics experiments using virtual reality or human-in-the-loop teleoperation of a simulated robotic system. The dynamic model is fast and robust while still providing results sufficiently accurate to be used to animate a humanoid character. It can also estimate internal joint forces used during a movement to create effort-contingent stimuli and support controlled experiments to measure the dynamics generating human behaviors systematically. The paper describes the innovative features that allow the model to integrate its dynamic equations accurately and illustrates its performance and accuracy with demonstrations. The model has a two-foot stance ability, capable of generating results comparable with an experiment done with subjects, and illustrates the uncontrolled manifold concept. Additionally, the model's facility to capture large energetic databases opens new possibilities for theorizing as to human movement function. The model is freely available.

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“…Although the subplate receives functional neuromodulatory inputs already at early stages (Hanganu and Luhmann, 2004 ; Dupont et al, 2006 ; Hanganu et al, 2009 ), cortical layers 2 to 6 are only gradually innervated in an inside first—out side last sequence (Calarco and Robertson, 1995 ; Mechawar and Descarries, 2001 ). The emergence of the neuromodulatory inputs accompanies the developmental switch from bursting to continuous desynchronized activity (Colonnese et al, 2010 ) and the developmental changes in vigilance states and active movements (Mukherjee et al, 2017 ; Dooley et al, 2020 ; Glanz et al, 2021 ). Thus, these neuromodulatory systems have a progressively stronger influence on spontaneous and sensory evoked cortical function during the early postnatal period.…”

Section: The Challenges Of Studying the Neurophysiology Of The Developing Cerebral Cortex In Rodentsmentioning

confidence: 99%

“…Furthermore, spontaneous self-generated movements (myoclonic twitches) can be already observed very early and play an important role in the development of the sensorimotor system (Inacio et al, 2016 ; Dooley et al, 2020 ; Gomez et al, 2021 ). Head-fixation of newborn rodents allows simultaneous recordings of large-scale neuronal activity and spontaneous movements of the animal's snout including the whiskers, the forelimbs, hindlimbs, and the tail using electromyography (EMG) or multiple video camera monitoring (Dooley and Blumberg, 2018 ; Glanz et al, 2021 ; Gomez et al, 2021 ). Neuronal structures involved in the generation or modulation of spontaneous movements in newborns can be studied with imaging or multi-electrodes recording techniques.…”

Section: Neurophysiology Of the Developing Cerebral Cortex: What We Have Learnedmentioning

confidence: 99%

“…CPGs and motor-related networks may trigger spontaneous movements, which subsequently activate the sensory system, thereby promoting the spatio-temporal binding of developing neuronal networks in the sensory-motor system. In the somatosensory and motor cortex of newborn rodents spindle burst and gamma oscillations mediate this binding process (Khazipov et al, 2004 , 2013 ; Yang et al, 2009 , 2013 ; Minlebaev et al, 2011 ; An et al, 2014 ; Luhmann and Khazipov, 2018 ; Dooley et al, 2020 ; Glanz et al, 2021 ).…”

Section: Neurophysiology Of the Developing Cerebral Cortex: What We Have Learnedmentioning

confidence: 99%

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Neurophysiology of the Developing Cerebral Cortex: What We Have Learned and What We Need to Know

Luhmann

2022

Front. Cell. Neurosci.

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This review article aims to give a brief summary on the novel technologies, the challenges, our current understanding, and the open questions in the field of the neurophysiology of the developing cerebral cortex in rodents. In the past, in vitro electrophysiological and calcium imaging studies on single neurons provided important insights into the function of cellular and subcellular mechanism during early postnatal development. In the past decade, neuronal activity in large cortical networks was recorded in pre- and neonatal rodents in vivo by the use of novel high-density multi-electrode arrays and genetically encoded calcium indicators. These studies demonstrated a surprisingly rich repertoire of spontaneous cortical and subcortical activity patterns, which are currently not completely understood in their functional roles in early development and their impact on cortical maturation. Technological progress in targeted genetic manipulations, optogenetics, and chemogenetics now allow the experimental manipulation of specific neuronal cell types to elucidate the function of early (transient) cortical circuits and their role in the generation of spontaneous and sensory evoked cortical activity patterns. Large-scale interactions between different cortical areas and subcortical regions, characterization of developmental shifts from synchronized to desynchronized activity patterns, identification of transient circuits and hub neurons, role of electrical activity in the control of glial cell differentiation and function are future key tasks to gain further insights into the neurophysiology of the developing cerebral cortex.

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Sensory Coding of Limb Kinematics in Motor Cortex across a Key Developmental Transition

Cited by 16 publications

References 59 publications

Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Computational Modeling: Human Dynamic Model

Neurophysiology of the Developing Cerebral Cortex: What We Have Learned and What We Need to Know

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