Your search keyword '"López-Azcárate, Jon"' showing total 4 results

1. High beta activity in the subthalamic nucleus and freezing of gait in Parkinson's disease.

Author

Toledo, Jon B., López-Azcárate, Jon, Garcia-Garcia, David, Guridi, Jorge, Valencia, Miguel, Artieda, Julio, Obeso, Jose, Alegre, Manuel, and Rodriguez-Oroz, Maria

Subjects

*PARKINSON'S disease patients, *HYPOKINESIA, *FREEZING, *NEUROPHYSIOLOGY, *ELECTRODES, *BRAIN stimulation, *PATHOLOGICAL physiology, *SUBTHALAMIC nucleus

Abstract

Abstract: Objective: Oscillatory activity in the beta band is increased in the subthalamic nucleus (STN) of Parkinson's disease (PD) patients. Rigidity and bradykinesia are associated with the low-beta component (13–20Hz) but the neurophysiological correlate of freezing of gait in PD has not been ascertained. Methods: We evaluated the power and coherence of the low- and high-beta bands in the STN and cortex (EEG) of PD patients with (p-FOG) (n=14) or without freezing of gait (n-FOG) (n=8) in whom electrodes for chronic stimulation in the STN had been implanted for treatment with deep brain stimulation. Results: p-FOG patients showed higher power in the high-beta band (F=11.6, p=0.002) that was significantly reduced after l-dopa administration along with suppression of FOG (F=4.6, p=0.042). High-beta cortico-STN coherence was maximal for midline cortical EEG electrodes, whereas the low-beta band was maximal for lateral electrodes (χ 2 =20.60, p<0.0001). Conclusions: The association between freezing of gait, high-beta STN oscillations and cortico-STN coherence suggests that this oscillatory activity might interfere in the frontal cortex–basal ganglia networks, thereby participating in the pathophysiology of FOG in PD. [Copyright &y& Elsevier]

Published

2014

2. Ketamine-Induced Oscillations in the Motor Circuit of the Rat Basal Ganglia.

Author

Nicolás, María Jesús, López-Azcárate, Jon, Valencia, Miguel, Alegre, Manuel, Pérez-Alcázar, Marta, Iriarte, Jorge, and Artieda, Julio

Subjects

*KETAMINE, *BASAL ganglia, *LABORATORY rats, *CEREBRAL cortex, *PATHOLOGICAL physiology, *NEUROLOGICAL disorders, *SCHIZOPHRENIA, *PARKINSON'S disease

Abstract

Oscillatory activity can be widely recorded in the cortex and basal ganglia. This activity may play a role not only in the physiology of movement, perception and cognition, but also in the pathophysiology of psychiatric and neurological diseases like schizophrenia or Parkinson's disease. Ketamine administration has been shown to cause an increase in gamma activity in cortical and subcortical structures, and an increase in 150 Hz oscillations in the nucleus accumbens in healthy rats, together with hyperlocomotion. We recorded local field potentials from motor cortex, caudate-putamen (CPU), substantia nigra pars reticulata (SNr) and subthalamic nucleus (STN) in 20 awake rats before and after the administration of ketamine at three different subanesthetic doses (10, 25 and 50 mg/Kg), and saline as control condition. Motor behavior was semiautomatically quantified by custom-made software specifically developed for this setting. Ketamine induced coherent oscillations in low gamma (∼50 Hz), high gamma (∼80 Hz) and high frequency (HFO, ∼150 Hz) bands, with different behavior in the four structures studied. While oscillatory activity at these three peaks was widespread across all structures, interactions showed a different pattern for each frequency band. Imaginary coherence at 150 Hz was maximum between motor cortex and the different basal ganglia nuclei, while low gamma coherence connected motor cortex with CPU and high gamma coherence was more constrained to the basal ganglia nuclei. Power at three bands correlated with the motor activity of the animal, but only coherence values in the HFO and high gamma range correlated with movement. Interactions in the low gamma band did not show a direct relationship to movement. These results suggest that the motor effects of ketamine administration may be primarily mediated by the induction of coherent widespread high-frequency activity in the motor circuit of the basal ganglia, together with a frequency-specific pattern of connectivity among the structures analyzed. [ABSTRACT FROM AUTHOR]

Published

2011

3. Coupling between Beta and High-Frequency Activity in the Human Subthalamic Nucleus May Be a Pathophysiological Mechanismin Parkinson's Disease.

Author

López-Azcárate, Jon, Tainta, Mikel, Rodríguez-Oroz, María C., Valencia, Miguel, González, Rafael, Guridi, Jorge, Iriarte, Jorge, Obeso, José A., Artieda, Julio, and Alegre, Manuel

Subjects

*PARKINSON'S disease, *CELL nuclei, *SUBTHALAMUS, *PATHOLOGICAL physiology, *BASAL ganglia

Abstract

In Parkinson's disease (PD), the oscillatory activity recorded from the basal ganglia shows dopamine-dependent changes. In the "off" parkinsonian motor state, there is prominent activity in the beta band (12-30 Hz) that is mostly attenuated after dopaminergic therapy ("on" medication state). The on state is also characterized by activity in the gamma (60-80 Hz) and high-frequency (300 Hz) bands that is modulated by movement. We recorded local field potentials from a group of 15 PD patients (three females) treated with bilateral deep brain stimulation of the subthalamic nucleus, using a high sampling rate (2 kHz) and filters suitable to study high-frequency activity (0.3-1000 Hz). We observed high-frequency oscillations (HFOs) in both the off and on motor states. In the off state, the amplitude of the HFOs was coupled to the phase of the abnormal beta activity. The beta-coupled HFOs showed little or even negative movement-related changes in amplitude. Moreover, the degree of movement-related modulation of the HFOs correlated negatively with the rigidity/ bradykinesia scores. In the on motor state, the HFOs were liberated from this beta coupling, and they displayed marked movement related amplitude modulation. Cross-frequency interactions between the phase of slow activities and the amplitude of fast frequencies have been attributed an important role in information processing in cortical structures. Our findings suggest that nonlinear coupling between frequencies may not only be a physiological mechanism (as shown previously) but also that it may participate in the pathophysiology of parkinsonism. [ABSTRACT FROM AUTHOR]

Published

2010

4. Dopaminergic modulation of the spectral characteristics in the rat brain oscillatory activity

Author

Valencia, Miguel, López-Azcárate, Jon, Nicolás, María Jesús, Alegre, Manuel, and Artieda, Julio

Subjects

*DOPAMINERGIC mechanisms, *SPECTRUM analysis, *LABORATORY rats, *BRAIN physiology, *PATHOLOGICAL physiology, *SCHIZOPHRENIA, *NEURAL stimulation

Abstract

Abstract: Oscillatory activity can be widely recorded in the brain. It has been demonstrated to play an important role not only in the physiology of movement, perception and cognition, but also in the pathophysiology of a variety of diseases. In frequency domain, neurophysiological recordings show a power spectrum (PSD) following a log (PSD)∝log (f)−β , that reveals an intrinsic feature of many complex systems in nature: the presence of a scale-free dynamics characterized by a power-law component (PLC). Here we analyzed the influence of dopaminergic drugs over the PLC of the oscillatory activity recorded from different locations of the rat brain. Dopamine (DA) is a neurotransmitter that is required for a number of physiological functions like normal feeding, locomotion, posturing, grooming and reaction time. Alterations in the dopaminergic system cause vast effects in the dynamics of the brain activity, that may be crucial in the pathophysiology of neurological (like Parkinson’s disease) or psychiatric (like schizophrenia) diseases. Our results show that drugs with opposite effects over the dopaminergic system, induce opposite changes in the characteristics of the PLC: DA agonists/antagonists cause the PLC to swing around a fulcrum point in the range of 20Hz. Changes in the harmonic component of the spectrum were also detected. However, differences between recordings are better explained by the modulation of the PLC than by narrow peak activities in particular frequency ranges. Our findings suggest that the brain operates in a state of self-organized criticality (SOC) that is sensitive to dopaminergic stimulation. Nevertheless, understanding of the interactions between the rhythmic (harmonic component) and arhythmic component (fractal component) of brain activity remains as a challenge, which should motivate future studies to explore these phenomena. [Copyright &y& Elsevier]

Published

2012