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1.
Int J Neurosci ; 120(7): 483-8, 2010 Jul.
Article in English | MEDLINE | ID: mdl-20583900

ABSTRACT

The effect of Qigong meditation on the hemodynamics of the prefrontal cortex was investigated by spectroscopy with a single-wavelength probe (650 nm) and confirmed by standard near-infrared spectroscopy with a dual-wavelength probe. Deoxyhemoglobin changes were recorded with the single-wavelength probe over the left prefrontal cortex during meditation by Qigong practitioners, and non-practitioners instructed in the technique. Practitioners showed a significant decrease in deoxyhemoglobin levels suggesting an increase in prefrontal activation during meditation. The results were confirmed in a second set of experiments with the standard dual-wavelength probe, in which significant differences in the decrease in deoxyhemoglobin and increase in oxyhemoglobin concentrations were observed in practitioners as compared with non-practitioners. The study thus provides evidence that Qigong meditation has a significant effect on prefrontal activation.


Subject(s)
Cerebrovascular Circulation/physiology , Hemoglobins/metabolism , Meditation/psychology , Prefrontal Cortex/physiology , Spectroscopy, Near-Infrared/methods , Adult , Biological Clocks/physiology , Evoked Potentials/physiology , Female , Hemoglobins/analysis , Humans , Male , Oxygen Consumption/physiology , Oxyhemoglobins/analysis , Oxyhemoglobins/metabolism , Prefrontal Cortex/blood supply , Up-Regulation/physiology
2.
J Biol Phys ; 36(2): 197-205, 2010 Mar.
Article in English | MEDLINE | ID: mdl-19688266

ABSTRACT

Many studies have demonstrated the presence of scale invariance and long-range correlation in animal and human neuronal spike trains. The methodologies to extract the fractal or scale-invariant properties, however, do not address the issue as to the existence within the train of fine temporal structures embedded in the global fractal organisation. The present study addresses this question in human spike trains by the chaos game representation (CGR) approach, a graphical analysis with which specific temporal sequences reveal themselves as geometric structures in the graphical representation. The neuronal spike train data were obtained from patients whilst undergoing pallidotomy. Using this approach, we observed highly structured regions in the representation, indicating the presence of specific preferred sequences of interspike intervals within the train. Furthermore, we observed that for a given spike train, the higher the magnitude of its scaling exponent, the more pronounced the geometric patterns in the representation and, hence, higher probability of occurrence of specific subsequences. Given its ability to detect and specify in detail the preferred sequences of interspike intervals, we believe that CGR is a useful adjunct to the existing set of methodologies for spike train analysis.

3.
Int J Neurosci ; 118(5): 657-66, 2008 May.
Article in English | MEDLINE | ID: mdl-18446582

ABSTRACT

Oxygenation changes in the left prefrontal cortex during language processing were assessed with near-infrared spectroscopy (NIRS). Oxyhemoglobin and deoxyhemoglobin concentrations at the Fp1 site during 5 min of resting with eyes closed (control), followed by 5 min of reading aloud, were monitored. A statistically significant change in the oxyhemoglobin concentration was observed by NIRS in all the subjects after execution of the experimental task. The observations of hyper-oxygenation as well as hypo-oxygenation in the present investigation extend past studies and suggest a complex phenomenon of activation that may be the result of a vascular steal mechanism, attenuated activation baselines, or active cortical deactivation.


Subject(s)
Cerebrovascular Circulation/physiology , Oxygen/blood , Prefrontal Cortex/metabolism , Reading , Spectroscopy, Near-Infrared , Adolescent , Adult , Dominance, Cerebral/physiology , Female , Hemoglobins/metabolism , Humans , Male , Neuropsychological Tests , Oxyhemoglobins/metabolism , Prefrontal Cortex/blood supply
4.
Biomed Eng Online ; 4: 1, 2005 Jan 04.
Article in English | MEDLINE | ID: mdl-15631635

ABSTRACT

BACKGROUND: Evolutionary autonomous agents are robots or robot simulations whose controller is a dynamical neural network and whose evolution occurs autonomously under the guidance of a fitness function without the detailed or explicit direction of an external programmer. They are embodied agents with a simple neural network controller and as such they provide the optimal forum by which sensorimotor interactions in a specified environment can be studied without the computational assumptions inherent in standard neuroscience. METHODS: Evolutionary autonomous agents were evolved that were able to perform identical movements under two different contexts, one which represented an automatic movement and one which had a symbolic context. In an attempt to model the automatic-voluntary dissociation frequently seen in ideomotor apraxia, lesions were introduced into the neural network controllers resulting in a behavioral dissociation with loss of the ability to perform the movement which had a symbolic context and preservation of the simpler, automatic movement. RESULTS: Analysis of the changes in the hierarchical organization of the networks in the apractic EAAs demonstrated consistent changes in the network dynamics across all agents with loss of longer duration time scales in the network dynamics. CONCLUSION: The concepts of determinate motor programs and perceptual representations that are implicit in the present day understanding of ideomotor apraxia are assumptions inherent in the computational understanding of brain function. The strength of the present study using EAAs to model one aspect of ideomotor apraxia is the absence of these assumptions and a grounding of all sensorimotor interactions in an embodied, autonomous agent. The consistency of the hierarchical changes in the network dynamics across all apractic agents demonstrates that this technique is tenable and will be a valuable adjunct to a computational formalism in the understanding of the physical basis of neurological disorders.


Subject(s)
Apraxias/physiopathology , Biomimetics/methods , Brain/physiopathology , Models, Neurological , Nerve Net/physiopathology , Neural Networks, Computer , Robotics/methods , Biological Evolution , Computer Simulation , Humans , Motor Skills , Visual Perception
5.
BMC Physiol ; 4: 7, 2004 Apr 27.
Article in English | MEDLINE | ID: mdl-15113424

ABSTRACT

BACKGROUND: The pulsatile nature of the arterial pulse induces a pulsatile perfusion pattern which can be observed in human cerebral cortex with non-invasive near-infrared spectroscopy. The present study attempts to establish a quantitative relation between these two events, even in situations of very weak signal-to-noise ratio in the cortical perfusion signal. The arterial pulse pattern was extracted from the left middle finger by means of plethesmographic techniques. Changes in cortical perfusion were detected with a continuous-wave reflectance spectrophotometer on the scalp overlying the left prefrontal cortex. Cross-correlation analysis was performed to provide evidence for a causal relation between the arterial pulse and relative changes in cortical total hemoglobin. In addition, the determination of the statistical significance of this relation was established by the use of phase-randomized surrogates. RESULTS: The results showed statistically significant cross correlation between the arterial and perfusion signals. CONCLUSIONS: The approach designed in the present study can be utilized for a quantitative and continuous assessment of the perfusion states of the cerebral cortex in experimental and clinical settings even in situations of extremely low signal-to-noise ratio.


Subject(s)
Cerebrovascular Circulation/physiology , Pulse , Adolescent , Adult , Female , Heart Rate , Humans , Male , Plethysmography/methods , Reference Values , Spectroscopy, Fourier Transform Infrared , Spectroscopy, Near-Infrared
6.
J Physiol Paris ; 98(4-6): 507-29, 2004.
Article in English | MEDLINE | ID: mdl-16290117

ABSTRACT

The problem of demarcating neural network space is formidable. A simple fully connected recurrent network of five units (binary activations, synaptic weight resolution of 10) has 3.2 *10(26) possible initial states. The problem increases drastically with scaling. Here we consider three complementary approaches to help direct the exploration to distinguish epileptic from healthy networks. [1] First, we perform a gross mapping of the space of five-unit continuous recurrent networks using randomized weights and initial activations. The majority of weight patterns (>70%) were found to result in neural assemblies exhibiting periodic limit-cycle oscillatory behavior. [2] Next we examine the activation space of non-periodic networks demonstrating that the emergence of paroxysmal activity does not require changes in connectivity. [3] The next challenge is to focus the search of network space to identify networks with more complex dynamics. Here we rely on a major available indicator critical to clinical assessment but largely ignored by epilepsy modelers, namely: behavioral states. To this end, we connected the above network layout to an external robot in which interactive states were evolved. The first random generation showed a distribution in line with approach [1]. That is, the predominate phenotypes were fixed-point or oscillatory with seizure-like motor output. As evolution progressed the profile changed markedly. Within 20 generations the entire population was able to navigate a simple environment with all individuals exhibiting multiply-stable behaviors with no cases of default locked limit-cycle oscillatory motor behavior. The resultant population may thus afford us a view of the architectural principles demarcating healthy biological networks from the pathological. The approach has an advantage over other epilepsy modeling techniques in providing a way to clarify whether observed dynamics or suggested therapies are pointing to computational viability or dead space.


Subject(s)
Brain Mapping/methods , Computer Simulation , Epilepsy/physiopathology , Models, Neurological , Nerve Net/physiopathology , Action Potentials/physiology , Algorithms , Animals , Biological Clocks/physiology , Epilepsy/therapy , Humans , Mathematics , Motor Neurons/physiology , Neural Networks, Computer , Neuronal Plasticity/physiology , Robotics
7.
Pain ; 31(2): 225-236, 1987 Nov.
Article in English | MEDLINE | ID: mdl-3501563

ABSTRACT

We have performed single unit analysis of the activity of cells located in the ventral nuclear group of thalamus in a patient with dysesthetic pain below the level of a clinically complete traumatic spinal cord transection at C5. Cells located in the parasagittal plane 14 mm lateral to the midline responded to tactile stimulation in small facial and intraoral receptive fields, which were characteristic of patients without somatosensory abnormality [30]. In this patient the 16 mm lateral parasagittal plane contained cells with receptive fields located on the occiput and neck instead of the upper extremity as would normally be expected. Cells with receptive fields on the neck and occiput had not previously been observed in recordings from single units (n = 531) responding to somatosensory stimulation [30]. Thus, on the basis of their location in a region of thalamus which normally represents parts of the body below the level of the spinal cord transection and their unusual receptive fields adjacent to these same parts of the body, we propose that the cells in the 16 mm lateral plane have lost their normal afferent input. Analysis of the autopower spectra of spike trains indicates that cells in the 16 mm lateral plane exhibited a higher mean firing rate and greater tendency to fire in bursts than cells in the 14 mm lateral plane (P less than 0.005). Finally, electrical stimulation at the recording sites in the 16 mm lateral plane evoked a burning sensation in the occiput, neck and upper extremity. These results suggest that regions of thalamus which have lost their normal somatosensory input contain neurons which exhibit abnormal spontaneous and evoked activity and that electrical stimulation of these regions can produce the sensation of burning dysesthesia.


Subject(s)
Pain/physiopathology , Spinal Cord Injuries/physiopathology , Thalamus/physiopathology , Action Potentials , Humans , Male , Microelectrodes , Middle Aged , Pain/etiology , Pain Management , Spinal Cord Injuries/complications , Transcutaneous Electric Nerve Stimulation
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