Your search keyword '"Chakrabarty S"' showing total 12 results

1. Pathophysiological mechanisms of impaired limb use and repair strategies for motor systems after unilateral injury of the developing brain.

Author

Friel KM, Chakrabarty S, and Martin JH

Subjects

Cerebral Palsy complications, Cerebral Palsy therapy, Humans, Infant, Motor Skills Disorders etiology, Motor Skills Disorders therapy, Prenatal Injuries etiology, Prenatal Injuries therapy, Cerebral Palsy physiopathology, Extremities physiology, Motor Skills Disorders physiopathology, Neuronal Plasticity physiology, Prenatal Injuries physiopathology, Pyramidal Tracts physiopathology

Abstract

The corticospinal tract (CST) is important for limb control. In humans, it begins developing prenatally but CST connections do not have a mature pattern until about 6 months of age and its capacity to evoke muscle contraction does not mature until mid-adolescence. An initially bilateral projection is subsequently refined, so that most ipsilateral CST connections are eliminated. Unilateral brain damage during refinement leads to bilateral developmental impairments. The damaged side develops sparse and weak contralateral spinal connections and the non-involved hemisphere maintains its ipsilateral projection to develop an aberrant bilateral spinal projection. In a kitten model of unilateral spastic cerebral palsy, we replicate key features of the CST circuit changes: robust bilateral CST projections from the non-involved hemisphere, sparse contralateral connections from the affected hemisphere, and motor impairments. We discuss the role of activity-dependent synaptic competition in development of bilateral CSTs and consider several experimental strategies for restoring a more normal pattern of CST connections from the damaged and non-involved sides. We highlight recent results stressing the importance of combined repair of CST axons, restoration of a more normal motor cortex motor representation, and key involvement of spinal cholinergic interneurons in restoring skilled motor function., (© The Authors. Developmental Medicine & Child Neurology © 2013 Mac Keith Press.)

Published

2013

2. Selective corticospinal tract injury in the rat induces primary afferent fiber sprouting in the spinal cord and hyperreflexia.

Author

Tan AM, Chakrabarty S, Kimura H, and Martin JH

Subjects

Afferent Pathways pathology, Animals, Male, Pyramidal Tracts pathology, Rats, Rats, Sprague-Dawley, Afferent Pathways physiopathology, Nerve Regeneration physiology, Neuronal Plasticity, Pyramidal Tracts injuries, Pyramidal Tracts physiopathology, Reflex, Abnormal

Abstract

The corticospinal tract (CST) has dense contralateral and sparse ipsilateral spinal cord projections that converge with proprioceptive afferents on common spinal targets. Previous studies in adult rats indicate that the loss of dense contralateral spinal CST connections after unilateral pyramidal tract section (PTx), which models CST loss after stroke or spinal cord injury, leads to outgrowth from the spared side into the affected, ipsilateral, spinal cord. The reaction of proprioceptive afferents after this CST injury, however, is not known. Knowledge of proprioceptive afferent responses after loss of the CST could inform mechanisms of maladaptive plasticity in spinal sensorimotor circuits after injury. Here, we hypothesize that the loss of the contralateral CST results in a reactive increase in muscle afferents from the impaired limb and enhancement of their physiological actions within the cervical spinal cord. We found that 10 d after PTx, proprioceptive afferents sprout into cervical gray matter regions denervated by the loss of CST terminations. Furthermore, VGlut1-positive boutons, indicative of group 1A afferent terminals, increased on motoneurons. PTx also produced an increase in microglial density within the gray matter regions where CST terminations were lost. These anatomical changes were paralleled by reduction in frequency-dependent depression of the H-reflex, suggesting hyperreflexia. Our data demonstrate for the first time that selective CST injury induces maladaptive afferent fiber plasticity remote from the lesion. Our findings suggest a novel structural reaction of proprioceptive afferents to the loss of CST terminations and provide insight into mechanisms underlying spasticity.

Published

2012

3. Using motor behavior during an early critical period to restore skilled limb movement after damage to the corticospinal system during development.

Author

Friel K, Chakrabarty S, Kuo HC, and Martin J

Subjects

Animals, Brain Damage, Chronic physiopathology, Cats, Female, Forelimb innervation, Male, Motor Skills Disorders physiopathology, Movement physiology, Neuronal Plasticity physiology, Paresis physiopathology, Pyramidal Tracts growth & development, Pyramidal Tracts physiopathology, Restraint, Physical methods, Brain Damage, Chronic rehabilitation, Forelimb physiopathology, Motor Skills physiology, Motor Skills Disorders rehabilitation, Paresis rehabilitation, Physical Therapy Modalities, Pyramidal Tracts injuries, Restraint, Physical physiology

Abstract

This study investigated the requirements for restoring motor function after corticospinal (CS) system damage during early postnatal development. Activity-dependent competition between the CS tracts (CSTs) of the two hemispheres is imperative for normal development. Blocking primary motor cortex (M1) activity unilaterally during a critical period [postnatal week 5 (PW5) to PW7] produces permanent contralateral motor skill impairments, loss of M1 motor map, aberrant CS terminations, and decreases in CST presynaptic sites and spinal cholinergic interneuron numbers. To repair these motor systems impairments and restore function, we manipulated motor experience in three groups of cats after this CST injury produced by inactivation. One group wore a jacket restraining the limb ipsilateral to inactivation, forcing use of the contralateral, impaired limb, for the month after M1 inactivation (PW8-PW13; "restraint alone"). A second group wore the restraint during PW8-PW13 and was also trained for 1 h/d in a reaching task with the contralateral forelimb ("early training"). To test the efficacy of intervention during adolescence, a third group wore the restraint and received reach training during PW20-PW24 ("delayed training"). Early training restored CST connections and the M1 motor map, increased cholinergic spinal interneurons numbers on the contralateral, relative to ipsilateral, side, and abrogated limb control impairments. Delayed training restored CST connectivity and the M1 motor map but not contralateral spinal cholinergic cell counts or motor performance. Restraint alone only restored CST connectivity. Our findings stress the need to reestablish the integrated functions of the CS system at multiple hierarchical levels in restoring skilled motor function after developmental injury.

Published

2012

4. Co-development of proprioceptive afferents and the corticospinal tract within the cervical spinal cord.

Author

Chakrabarty S and Martin JH

Subjects

Afferent Pathways anatomy & histology, Afferent Pathways growth & development, Animals, Cats, Electric Stimulation, Electrophysiology methods, Cervical Vertebrae, Proprioception physiology, Pyramidal Tracts anatomy & histology, Pyramidal Tracts growth & development, Spinal Cord anatomy & histology, Spinal Cord growth & development

Abstract

In maturity, skilled movements depend on coordination of control signals by descending pathways, such as the corticospinal tract (CST), and proprioceptive afferents (PAs). An important locus for this coordination is the spinal cord intermediate zone. Convergence of CST and PA terminations onto common regions leads to interactions that may underlie afferent gating and modulation of descending control signals during movements. We determined establishment of CST and PA terminations within common spinal cord regions and development of synaptic interactions in 4-week-old cats, which is before major spinal motor circuit refinement, and two ages after refinement (weeks 8, 11). We examined the influence of one or the other system on monosynaptic responses, on the spinal cord surface and locally in the intermediate zone, evoked by either CST or deep radial nerve (DRN) stimulation. DRN stimulation suppressed CST monosynaptic responses at 4 weeks, but this converted to facilitation by 8 weeks. This may reflect a strategy to limit CST movement control when it has aberrant immature connections, and could produce errant movements. CST stimulation showed delayed development of mixed suppression and facilitation of DRN responses. We found development of age-dependent overlap of PA and CST terminations where interactions were recorded in the intermediate zone. Our findings reveal a novel co-development of different inputs onto common spinal circuits and suggest a logic to CST-PA interactions at an age before the CST has established connectional specificity with spinal circuits., (© 2011 The Authors. European Journal of Neuroscience © 2011 Federation of European Neuroscience Societies and Blackwell Publishing Ltd.)

Published

2011

5. Harnessing activity-dependent plasticity to repair the damaged corticospinal tract in an animal model of cerebral palsy.

Author

Martin JH, Chakrabarty S, and Friel KM

Subjects

Animals, Pyramidal Tracts pathology, Cats, Cerebral Palsy pathology, Cerebral Palsy physiopathology, Cerebral Palsy therapy, Disease Models, Animal, Neuronal Plasticity physiology, Pyramidal Tracts physiology

Abstract

The corticospinal tract (CST) is the principal motor control pathway for skilled movements. It has a protracted postnatal development, creating a protracted period of vulnerability to perinatal brain and spinal cord injury. Research has shown that the motor signs in cerebral palsy (CP) reflect the loss of CST connections as well as development of abnormal motor systems connections, especially between the developing CST and spinal motor circuits. In this paper, we discuss a feline model of CP that we have developed. The animals develop a pattern of abnormal CST connections that is remarkably similar to that seen in hemiplegic CP and visuomotor impairments. Using this model we devised neural activity-based therapeutic approaches to repair the abnormal CST connections and restore normal skilled movement control. Our studies stress that more active CST connections are better able to maintain strong synaptic connections with spinal motor circuits. We propose that perinatal trauma initiates a vicious cycle in which CST axons that are spared after an injury are at a disadvantage for maintaining spinal connections, leading to further reductions in connections and motor signs. If this is so, targeted activation of the spared CST might interrupt this process and lead to functional improvement., (© The Authors. Developmental Medicine & Child Neurology © 2011 Mac Keith Press.)

Published

2011

6. Postnatal development of a segmental switch enables corticospinal tract transmission to spinal forelimb motor circuits.

Author

Chakrabarty S and Martin JH

Subjects

Animals, Anterior Horn Cells physiology, Axons physiology, Calcium-Binding Proteins metabolism, Cats, Choline O-Acetyltransferase metabolism, Electric Stimulation, Evoked Potentials, Interneurons physiology, Microscopy, Confocal, Motor Cortex growth & development, Motor Skills physiology, Pyramidal Tracts cytology, Pyramidal Tracts growth & development, Synaptic Potentials, Time Factors, Motor Cortex physiology, Pyramidal Tracts physiology

Abstract

Development of skilled movements and the corticospinal tract (CST) begin prenatally and continue postnatally. Because the CST is required for skilled movements in maturity, it is accepted that motor skills cannot occur until the CST develops a mature organization. We recently showed that the CST plays an essential role in postnatal development of interneurons comprising the spinal circuits it engages. We proposed that CST signals are more effectively transmitted to ventral motor circuits after interneuron maturation, thereby enabling expression of CST motor functions, suggesting development of a segmental switch promoting transmission. We tested this by recording CST-evoked focal synaptic potentials, extracellularly, in the cervical enlargement of cats before and after interneuron maturation [postnatal week 5 (PW5) to PW7]. We compared monosynaptic CST amplitude input to segmental circuits with oligosynaptic ventral horn responses, as a measure of CST-evoked segmental response transmission from input to output. The M1 primary motor cortex was unilaterally inactivated between PW5 and PW7 to determine activity dependence. CST interneuron contacts were identified using confocal microscopy. CST terminals contact diverse interneuron classes. CST stimulation strongly activated ventral motor circuits at the ages when both interneurons and CST spinal terminations have developed a mature phenotype, supporting development of segmental transmission of CST signals. CST activity blockade impeded development of effective segmental transmission by the inactivated CST and created a novel path for transmission from the ipsilateral, unaffected, CST. Our findings show that development of segmental CST signal transmission regulates nascent CST motor control functions and provide insight into systems-level mechanisms for protracted motor skill development.

Published

2010

7. Activity-dependent codevelopment of the corticospinal system and target interneurons in the cervical spinal cord.

Author

Chakrabarty S, Shulman B, and Martin JH

Subjects

Action Potentials physiology, Animals, Cats, Cell Differentiation physiology, Cervical Vertebrae enzymology, Choline O-Acetyltransferase biosynthesis, Choline O-Acetyltransferase genetics, Female, Interneurons cytology, Interneurons enzymology, Neurogenesis physiology, Pyramidal Tracts enzymology, Spinal Cord cytology, Spinal Cord enzymology, Spinal Cord growth & development, Cervical Vertebrae growth & development, Cervical Vertebrae innervation, Interneurons physiology, Pyramidal Tracts growth & development

Abstract

Corticospinal tract (CST) connections to spinal interneurons are conserved across species. We identified spinal interneuronal populations targeted by the CST in the cervical enlargement of the cat during development. We focused on the periods before and after laminar refinement of the CST terminations, between weeks 5 and 7. We used immunohistochemistry of choline acetyltransferase (ChAT), calbindin, calretinin, and parvalbumin to mark interneurons. We first compared interneuron marker distribution before and after CST refinement. ChAT interneurons increased, while calbindin interneurons decreased during this period. No significant changes were noted in parvalbumin and calretinin. We next used anterograde labeling to determine whether the CST targets different interneuron populations before and after the refinement period. Before refinement, the CST terminated sparsely where calbindin interneurons were located and spared ChAT interneurons. After refinement, the CST no longer terminated in calbindin-expressing areas but did so where ChAT interneurons were located. Remarkably, early CST terminations were dense where ChAT interneurons later increased in numbers. Finally, we determined whether corticospinal system activity was necessary for the ChAT and calbindin changes. We unilaterally inactivated M1 between weeks 5 and 7 by muscimol infusion. Inactivation resulted in a distribution of calbindin and ChAT in spinal gray matter regions where the CST terminates that resembled the immature more than mature pattern. Our results show that the CST plays a crucial role in restructuring spinal motor circuits during development, possibly through trophic support, and provide strong evidence for the importance of connections with key spinal interneuron populations in development of motor control functions.

Published

2009

8. Activity-dependent plasticity improves M1 motor representation and corticospinal tract connectivity.

Author

Chakrabarty S, Friel KM, and Martin JH

Subjects

Age Factors, Analysis of Variance, Animals, Attention, Biophysics, Brain Mapping, Cats, Electric Stimulation, Functional Laterality physiology, GABA Agonists pharmacology, Motor Cortex drug effects, Muscimol pharmacology, Statistics, Nonparametric, Motor Cortex cytology, Motor Cortex physiology, Movement physiology, Neuronal Plasticity physiology, Pyramidal Tracts physiology

Abstract

Motor cortex (M1) activity between postnatal weeks 5 and 7 is essential for normal development of the corticospinal tract (CST) and visually guided movements. Unilateral reversible inactivation of M1, by intracortical muscimol infusion, during this period permanently impairs development of the normal dorsoventral distribution of CST terminations and visually guided motor skills. These impairments are abrogated if this M1 inactivation is followed by inactivation of the contralateral, initially active M1, from weeks 7 to 11 (termed alternate inactivation). This later period is when the M1 motor representation normally develops. The purpose of this study was to determine the effects of alternate inactivation on the motor representation of the initially inactivated M1. We used intracortical microstimulation to map the left M1 1 to 2 mo after the end of left M1 muscimol infusion. We compared representations in the unilateral inactivation and alternate inactivation groups. Alternate inactivation converted the sparse proximal M1 motor representation produced by unilateral inactivation to a complete and high-resolution proximal-distal representation. The motor map was restored by week 11, the same age that our present and prior studies demonstrated that alternate inactivation restored CST spinal connectivity. Thus M1 motor map developmental plasticity closely parallels plasticity of CST spinal terminations. After alternate inactivation reestablished CST connections and the motor map, an additional 3 wk was required for motor skill recovery. Since motor map recovery preceded behavioral recovery, our findings suggest that the representation is necessary for recovering motor skills, but additional time, or experience, is needed to learn to take advantage of the restored CST connections and motor map.

Published

2009

9. Presynaptic control of transmission through group II muscle afferents in the midlumbar and sacral segments of the spinal cord is independent of corticospinal control.

Author

Aggelopoulos NC, Chakrabarty S, and Edgley SA

Subjects

Electric Stimulation, Excitatory Postsynaptic Potentials physiology, Inhibitory Postsynaptic Potentials physiology, Lumbar Vertebrae, Muscle Tonus physiology, Neural Conduction physiology, Neural Inhibition physiology, Reflex physiology, Sacrum, Synaptic Transmission physiology, Afferent Pathways physiology, Motor Cortex physiology, Muscle, Skeletal innervation, Presynaptic Terminals physiology, Pyramidal Tracts physiology, Spinal Cord physiology, Spinal Nerve Roots physiology

Abstract

Transmission of information from the terminals group II muscle afferents is subject to potent presynaptic modulation by both segmental group II and cutaneous afferents and by descending monoaminergic systems. Currently it is unknown whether descending corticospinal fibres affect this transmission. Here we have examined whether corticospinal tract activation modulates the size of monosynaptic focal synaptic potentials (FSPs) evoked by group II muscle afferents, and the excitability of intraspinal terminals of group II afferents, both of which are indices used to show presynaptic control. Conditioning stimulation of corticospinal pathways had no effects on the sizes of group II evoked FSPs in the midlumbar or sacral segments at either dorsal horn or intermediate zone locations. These stimuli also had no effect on the excitability of single group II afferent terminals in the dorsal horn of the midlumbar segments. As positive controls, we verified that the corticospinal conditioning stimuli used did effectively depress FSPs evoked from cutaneous afferents recorded at the same spinal locations as the group II field potentials in all experiments. Corticospinal tract conditioning stimuli did not consistently enhance or reduce the depression of group II FSPs that was evoked by stimulation of ipsilateral segmental group II or cutaneous afferents; in the large majority of cases there was no effect. The results reveal that the control of transmission of information from group II afferents in these regions of the spinal cord is independent of direct corticospinal control.

Published

2008

10. Electrical stimulation of spared corticospinal axons augments connections with ipsilateral spinal motor circuits after injury.

Author

Brus-Ramer M, Carmel JB, Chakrabarty S, and Martin JH

Subjects

Animals, Disease Models, Animal, Efferent Pathways physiopathology, Female, Neuronal Plasticity, Pyramidal Tracts injuries, Pyramidal Tracts pathology, Rats, Rats, Sprague-Dawley, Recovery of Function, Spinal Cord Injuries pathology, Axons pathology, Electric Stimulation Therapy methods, Functional Laterality, Medulla Oblongata injuries, Pyramidal Tracts physiopathology, Spinal Cord Injuries therapy

Abstract

Activity-dependent competition shapes corticospinal (CS) axon outgrowth in the spinal cord during development. An important question in neural repair is whether activity can be used to promote outgrowth of CS axons in maturity. After injury, spared CS axons sprout and make new connections, but often not enough to restore function. We propose that electrically stimulating spared axons after injury will enhance sprouting and strengthen connections with spinal motor circuits. To study the effects of activity, we electrically stimulated CS tract axons in the medullary pyramid. To study the effects of injury, one pyramid was lesioned. We studied sparse ipsilateral CS projections of the intact pyramid as a model of the sparse connections preserved after CNS injury. We determined the capacity of CS axons to activate ipsilateral spinal motor circuits and traced their spinal projections. To understand the separate and combined contributions of injury and activity, we examined animals receiving stimulation only, injury only, and injury plus stimulation. Both stimulation and injury alone strengthened CS connectivity and increased outgrowth into the ipsilateral gray matter. Stimulation of spared axons after injury promoted outgrowth that reflected the sum of effects attributable to activity and injury alone. CS terminations were densest within the ventral motor territories of the cord, and connections in these animals were significantly stronger than after injury alone, indicating that activity augments injury-induced plasticity. We demonstrate that activity promotes plasticity in the mature CS system and that the interplay between activity and injury preferentially promotes connections with ventral spinal motor circuits.

Published

2007

11. Activity- and use-dependent plasticity of the developing corticospinal system.

Author

Martin JH, Friel KM, Salimi I, and Chakrabarty S

Subjects

Animals, Cats, Spinal Cord growth & development, Spinal Cord physiology, Neuronal Plasticity physiology, Neurons physiology, Pyramidal Tracts cytology, Pyramidal Tracts growth & development, Pyramidal Tracts physiology, Spinal Cord cytology

Abstract

The corticospinal (CS) system, critical for controlling skilled movements, develops during the late prenatal and early postnatal periods in all species examined. In the cat, there is a sequence of development of the mature pattern of terminations of CS tract axons in the spinal gray matter, followed by motor map development of the primary motor cortex. Skilled limb movements begin to be expressed as the map develops. Development of the proper connections between CS axons and spinal neurons in cats depends on CS neural activity and motor behavioral experience during a critical postnatal period. Reversible CS inactivation or preventing limb use produces an aberrant distribution of CS axon terminations and impairs visually guided movements. This altered pattern of CS connections after inactivation in cats resembles the aberrant pattern of motor responses evoked by transcranial magnetic stimulation in hemiplegic cerebral palsy patients. Left untreated in the cat, these impairments do not resolve. We have found that activity-dependent processes can be harnessed in cats to reestablish normal CS connections and function. This finding suggests that aspects of normal CS connectivity and function might some day be restored in hemiplegic cerebral palsy.

Published

2007

12. Presynaptic control of transmission through group II muscle afferents in the midlumbar and sacral segments of the spinal cord is independent of corticospinal control

Author

Steve A. Edgley, NC Aggelopoulos, Samit Chakrabarty, Chakrabarty, S [0000-0002-4389-8290], and Apollo - University of Cambridge Repository

Subjects

Sacrum, Neuroscience(all), Central nervous system, Neural Conduction, Presynaptic Terminals, Pyramidal Tracts, Neurotransmission, Synaptic Transmission, 03 medical and health sciences, 0302 clinical medicine, Reflex, Medicine, Evoked potential, Muscle, Skeletal, 030304 developmental biology, Synaptic potential, Afferent Pathways, 0303 health sciences, Lumbar Vertebrae, Pyramidal tracts, business.industry, General Neuroscience, Motor Cortex, Excitatory Postsynaptic Potentials, Neural Inhibition, Anatomy, Spinal cord, Electric Stimulation, Electrophysiology, medicine.anatomical_structure, Inhibitory Postsynaptic Potentials, Spinal Cord, Muscle Tonus, Corticospinal tract, Spinal Nerve Roots, business, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Transmission of information from the terminals group II muscle afferents is subject to potent presynaptic modulation by both segmental group II and cutaneous afferents and by descending monoaminergic systems. Currently it is unknown whether descending corticospinal fibres affect this transmission. Here we have examined whether corticospinal tract activation modulates the size of monosynaptic focal synaptic potentials (FSPs) evoked by group II muscle afferents, and the excitability of intraspinal terminals of group II afferents, both of which are indices used to show presynaptic control. Conditioning stimulation of corticospinal pathways had no effects on the sizes of group II evoked FSPs in the midlumbar or sacral segments at either dorsal horn or intermediate zone locations. These stimuli also had no effect on the excitability of single group II afferent terminals in the dorsal horn of the midlumbar segments. As positive controls, we verified that the corticospinal conditioning stimuli used did effectively d epress FSPs evoked from cutaneous afferents recorded at the same spinal locations as the group II field potentials in all experiments. Corticospinal tract conditioning stimuli did not consistently enhance or reduce the depression of group II FSPs that was evoked by stimulation of ipsilateral segmental group II or cutaneous afferents; in the large majority of cases there was no effect. The results reveal that the control of transmission of information from group II afferents in these regions of the spinal cord is independent of direct corticospinal control.

Published

2008