Spatiotemporal beanformer analysis of neuromagnetic activity in sensorimotor cortex: rhythmic perception, production and sensorimotor coordination

Unknown Date

Research presented in this dissertation has the central aim of applying a novel method of source localization called beamforming to neuromagnetic recordings for characterizing dynamic spatiotemporal activity of sensorimotor brain processes in subjects during rhythmic auditory stimulation, self-paced movement, and two sensorimotor coordination (synchronization and syncopation) tasks known to differentiate on the basis of behavioral stability. Each experimental condition was performed at different rates resulting in 26 experimental runs per subject. Event-related neural responses were recorded with a whole-head MEG system and characterized in terms of their phase-locked (evoked) and non-phase-locked (induced) activity within the brain using both whole-brain analysis and region of interest (ROI) analysis. The analysis of the auditory conditions revealed that neural activity within extraauditory areas throughout the brain, including sensorimotor cortex, is modulated by rhythmic auditory stimulation. Additionally, the temporal profile of this activity was markedly different between sensorimotor and auditory cortex, possibly revealing different physiological processes, entrained within a common network for representing isochronic auditory events. During self-paced movements cycle-by-cycle dynamics of induced neural activity was measured and consistent neuro-modulation in the form of event-related desynchronization (ERD) and synchronization (ERS) was observed at all rates investigated (0.25 - 1.75Hz). ERD and ERS modulations exhibited dynamic scaling properties on a cycle-by-cycle basis that depended on the period of movement. Activity in the beta- and mu-bands also exhibited patterns of phase locking between sensorimotor locations. Phase locking patterns exhibited abrupt decreases with increases in movement rate. / During sensorimotor coordination tasks, the effect of temporal positioning of the auditory stimulus was apparent within sensorimotor cortical sites. This finding offers direct source level support for previous sensor level analysis revealing a differentiation of functional specificity for mu- and beta-band activity (Chen, Ding, Kelso, 2003; Jantzen, Fuchs, Mayville et al., 2001; Mayville, Fuchs, Ding et al., 2001), and may be reflective of specific coupling mechanisms between auditory and sensorimotor networks. The beamformer analysis applied within this dissertation successfully characterized large-scale neural networks during a variety of rhythmic perceptual, motor, and sensorimotor tasks resulting in the general message that information processes across disparate parts of the brain from different sensory, motor, and cognitive modalities appear to have the ability for widespread integration. / by Paul Ferrari. / Thesis (Ph.D.)--Florida Atlantic University, 2009. / Includes bibliography. / Electronic reproduction. Boca Raton, Fla., 2009. Mode of access: World Wide Web.

Sensorimotor integration

Perceptual-motor processes

Auditory provoked response

Brain mapping

The Human Intruder Test: An Anxiety Assessment in Rhesus Macaques (Macaca Mulatta)

Peterson, Emily J

23 November 2015

The human intruder test (HIT) is a noninvasive tool widely used for assessing anxiety in rhesus macaques (Macaca mulatta). This thesis explores the HIT procedure and applies it to a population of monkeys with a self-injurious behavioral pathology. Individual variation on this test can be used to assess anxiety and temperament. The first experiment of this thesis applied two different procedures of the HIT to 17 monkeys at UMass. Monkeys displayed little response to the intruder, and no significant differences were detected for the two procedures. To determine whether these responses were unique to the UMass monkeys, their behavior was then compared to the behavior of monkeys at three other primate facilities. UMass monkeys showed less of a reaction compared to monkeys at other facilities. They came to the front of the cage when the intruder entered the room whereas the monkeys at other facilities moved to the back and showed virtually no threats to the intruder. One possible explanation is the increased exposure to humans that UMass monkeys experience. Even though the human running the HIT was a stranger, monkeys at UMass may not perceive a new human in front of their cage to be a threat. The second experiment tested the hypothesis that monkeys with a record of self-injurious behavior (SIB) would be more anxious in response to the HIT. The cage-side version of the HIT was applied to 41 monkeys with a record of self-injurious behavior and 36 matched controls. In contrast to our prediction, SIB subjects spent significantly less time showing anxious behavior and aggressive behavior toward the intruder as well as spent more time in the front of the cage. SIB subjects showed the same range of behaviors as controls, but significantly less behavioral change overall. These data add to the evidence from experiment one that the HIT may not be a sufficient novelty test to elicit a response in monkeys who are more often exposed to different people. An alternative explanation is that SIB is associated with a depressive like syndrome based on reduced overall activity and possibly lowered affect during the stare phase.

Anxiety

rhesus macaque

Human Intruder Test

Self-injurious behavior

provoked response

Behavioral Neurobiology

Mental Disorders

Other Animal Sciences

Veterinary Pathology and Pathobiology

Zoology