Dynamic encoding of movement direction in motor cortical neurons
Rickert J, Riehle A, Aertsen A, Rotter S, Nawrot MP (2009) Dynamic encoding of movement direction in motor cortical neurons. Journal of Neuroscience (in press)
When we perform a skilled movement such as reaching for an object, we can make use of prior information, for example about the object's location in space. This helps us to prepare the movement, and we gain improved accuracy and speed during movement execution. Here we investigate how prior information affects the motor cortical representation of movements during preparation and execution. We trained two monkeys in a delayed reaching task and provided a varying degree of prior information about the final target location. We decoded movement direction from multiple single unit activity recorded from the primary motor cortex (M1) in one monkey, and from the dorsal premotor cortex (PMd) in a second monkey. Our results demonstrate that motor cortical cells in both areas exhibit individual encoding characteristics that change dynamically in time and dependent on prior information. On the population level, the information about movement direction is at any point in time accurately represented in a neuronal ensemble of time-varying composition. We conclude that movement representation in the motor cortex is not a static one, but one where neurons dynamically allocate their computational resources to meet the demands defined by the movement task and the movements context. Consequently, we find that the decoding accuracy decreases if the precise task time, or the prior information that was available to the monkey, were disregarded in the decoding process. An optimal strategy for the read out of movement parameters from motor cortex should therefore take into account time and contextual parameters.