Inner space: Reference frames

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Inner space: Reference frames Aaron Batista Current Biology Volume 12, Issue 11, Pages R380-R383 (June 2002) DOI: 10.1016/S0960-9822(02)00878-3

Fig. 1 When we catch a baseball the position of the ball is first registered in a retinal reference frame (1). The brain computes its position with respect to the hand (2), then determines the muscle contractions needed to rotate the joints of the arm and shoulder (3) in order to bring the glove on target with the ball. These three phases of the reach map onto distinct areas of the cerebral cortex, as highlighted in the sketch of the monkey brain. Current Biology 2002 12, R380-R383DOI: (10.1016/S0960-9822(02)00878-3)

Fig. 2 Some reference frames.Panel A shows two neurons (top and bottom graphs) recorded in posterior parietal cortex. These cells have retinotopic receptive fields that are gain modulated by eye position. The two curves within each graph differ due to the different directions of gaze. Panel B shows a neuron from parietal area VIP with a head-centered receptive field. Each of the nine color plots shows the neural response in screen coordinates for nine different fixation positions, indicated by the small white cross. In the two lower plots, the contours for four of these mappings are superimposed in either screen (left) or eye (right) coordinates. They show better alignment in screen coordinates. Panel C illustrates an area MIP neuron that encodes a reach plan in retinal coordinates. In each panel, the schematic diagram shows four different configurations of the monkey's eye and initial hand position. Below the schematics are the neuron's responses for reaches to the same four targets. The E and H indicate the eye and initial hand position relative to the targets. Each plot shows the neuron's response over time as the monkey plans then performs a reach to the target at that position. The reach plan that generates the largest response is always the one directly below the eyes, regardless of where the hand begins. Panel D shows a neuron from premotor cortex that has a receptive field in arm-centered coordinates. Each row depicts neural activity over time as visual stimuli approach the monkey along four different paths. For each row, a different combination of eye or hand position is used. In the first three rows, the arm is at the same position, to the right, and the monkey fixates in three different positions. The response field does not change. However, in the last row, when the arm is moved to the left, the response field moves along with it. This neuron also had a somatosensory response on the elbow, as indicated by the shading in the schematic. (Panel A from Andersen et al. (1985). Science 230, 456–458. Panel B from Duhamel et al. (1997). Panel C from Batista, A.P., Buneo, C.A., Snyder, L.H. and Andersen, R.A. (1999). Science 285, 257–260. Panel D from Graziano et al. (1994)). Current Biology 2002 12, R380-R383DOI: (10.1016/S0960-9822(02)00878-3)