Your search keyword '"Akam T"' showing total 2 results

1. Analogue closed-loop optogenetic modulation of hippocampal pyramidal cells dissociates gamma frequency and amplitude

Author

Nicholson, E, Kuzmin, D, Leite, M, Akam, T, and Kullmann, D

Subjects

Neurons, closed-loop, Time Factors, Mouse, Quantitative Biology::Neurons and Cognition, QH301-705.5, Pyramidal Cells, Science, Action Potentials, Hippocampus, Mice, Inbred C57BL, Optogenetics, Animals, Gamma Rhythm, Medicine, gamma oscillations, Biology (General), phase response curve, Research Article, Neuroscience

Abstract

Gamma-band oscillations are implicated in modulation of attention, integration of sensory information and flexible communication among anatomically connected brain areas. How networks become entrained is incompletely understood. Specifically, it is unclear how the spectral and temporal characteristics of network oscillations can be altered on rapid timescales needed for efficient communication. We use closed-loop optogenetic modulation of principal cell excitability in mouse hippocampal slices to interrogate the dynamical properties of hippocampal oscillations. Gamma frequency and amplitude can be modulated bi-directionally, and dissociated, by phase-advancing or delaying optogenetic feedback to pyramidal cells. Closed-loop modulation alters the synchrony rather than average frequency of action potentials, in principle avoiding disruption of population rate-coding of information. Modulation of phasic excitatory currents in principal neurons is sufficient to manipulate oscillations, suggesting that feed-forward excitation of pyramidal cells has an important role in determining oscillatory dynamics and the ability of networks to couple with one another.

Published

2018

2. Open-source, Python-based, hardware and software for controlling behavioural neuroscience experiments.

Author

Akam T, Lustig A, Rowland JM, Kapanaiah SK, Esteve-Agraz J, Panniello M, Márquez C, Kohl MM, Kätzel D, Costa RM, and Walton ME

Subjects

Animals, Computers, Mice, Reproducibility of Results, Software, Behavioral Sciences methods

Abstract

Laboratory behavioural tasks are an essential research tool. As questions asked of behaviour and brain activity become more sophisticated, the ability to specify and run richly structured tasks becomes more important. An increasing focus on reproducibility also necessitates accurate communication of task logic to other researchers. To these ends, we developed pyControl, a system of open-source hardware and software for controlling behavioural experiments comprising a simple yet flexible Python-based syntax for specifying tasks as extended state machines, hardware modules for building behavioural setups, and a graphical user interface designed for efficiently running high-throughput experiments on many setups in parallel, all with extensive online documentation. These tools make it quicker, easier, and cheaper to implement rich behavioural tasks at scale. As important, pyControl facilitates communication and reproducibility of behavioural experiments through a highly readable task definition syntax and self-documenting features. Here, we outline the system's design and rationale, present validation experiments characterising system performance, and demonstrate example applications in freely moving and head-fixed mouse behaviour., Competing Interests: TA Consulting contract with Open Ephys Production Site, AL, JR, SK, JE, MP, CM, MK, DK, RC, MW No competing interests declared, (© 2022, Akam et al.)

Published

2022