1 / 40

Understanding Vibration Discrimination and Neuronal Coding in the Somatosensory Cortex

This compilation features comprehensive figures illustrating the vibration discrimination task and its performance, alongside detailed insights into neuronal coding of vibration frequency in the primary somatosensory cortex (SI). The collection includes data on neuronal activity characterized by firing-rate coefficients and explores the influence of artificial stimuli. Additional emphasis is placed on cortical regions involved in comparative tasks, responses of inferotemporal neurons in macaques to visual stimuli, and the interconnectedness of visual processing pathways.

sauda
Télécharger la présentation

Understanding Vibration Discrimination and Neuronal Coding in the Somatosensory Cortex

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Photo, p. 476 Ranulfo Romo

  2. Figure 23.1 Vibration Discrimination Task and Performance

  3. Figure 23.1 Vibration Discrimination Task and Performance (Part 1)

  4. Figure 23.1 Vibration Discrimination Task and Performance (Part 2)

  5. Figure 23.2 Neuronal Coding of Vibration Frequency in Primary Somatosensory Cortex (SI)

  6. Figure 23.2 Neuronal Coding of Vibration Frequency in Primary Somatosensory Cortex (SI)(Part 1)

  7. Figure 23.2 Neuronal Coding of Vibration Frequency in Primary Somatosensory Cortex (SI)(Part 2)

  8. Figure 23.3 Replacement of Vibrations by Artificial Stimuli

  9. Figure 23.3 Replacement of Vibrations by Artificial Stimuli (Part 1)

  10. Figure 23.3 Replacement of Vibrations by Artificial Stimuli (Part 2)

  11. Figure 23.3 Replacement of Vibrations by Artificial Stimuli (Part 3)

  12. Figure 23.4 Neuronal Activity in SI Cortex Characterized by Firing-Rate Coefficients a1 and a2

  13. Figure 23.5 Cortical Regions Involved in the Vibration Comparison Task

  14. Figure 23.6 Neuronal Activity beyond SI Characterized by Firing Rate Coefficients a1 and a2

  15. Figure 23.6 Neuronal Activity beyond SI Characterized by Firing Rate Coefficients a1 and a2(Part 1)

  16. Figure 23.6 Neuronal Activity beyond SI Characterized by Firing Rate Coefficients a1 and a2(Part 2)

  17. Figure 23.7 Time Course of Response Parameters throughout the Trial Period

  18. Figure 23.7 Time Course of Response Parameters throughout the Trial Period (Part 1)

  19. Figure 23.7 Time Course of Response Parameters throughout the Trial Period (Part 2)

  20. Figure 23.8 Ventral Intracortical Visual Pathways

  21. Figure 23.9 Face-Selective Neurons in Temporal Lobe

  22. BOX 23.1 Functional Magnetic Resonance ImagingBrain Activity as Revealed by Averaging fMRI Scans across a Group of 20 Subjects

  23. Figure 23.10 Brain Activation Directly Correlated with Face Perception

  24. Figure 23.11 Responses of Macaque Monkey Inferotemporal Neurons to Changes in Viewing Angle and Stimulus Size

  25. Figure 23.11 Responses of Macaque Monkey Inferotemporal Neurons to Changes in Viewing Angle and Stimulus Size (Part 1)

  26. Figure 23.11 Responses of Macaque Monkey Inferotemporal Neurons to Changes in Viewing Angle and Stimulus Size (Part 2)

  27. Figure 23.11 Responses of Macaque Monkey Inferotemporal Neurons to Changes in Viewing Angle and Stimulus Size (Part 3)

  28. Figure 23.12 Schematic Organization of M, P, and K Channels to Visual Cortex

  29. Figure 23.12 Schematic Organization of M, P, and K Channels to Visual Cortex (Part 1)

  30. Figure 23.12 Schematic Organization of M, P, and K Channels to Visual Cortex (Part 2)

  31. Figure 23.13 Involvement of MT in Tracking Visual Motion

  32. Figure 23.14 The Direction of Eye Movements Can Be Altered by Electrical Stimulation in Area MT

  33. Figure 23.14 The Direction of Eye Movements Can Be Altered by Electrical Stimulation in Area MT (Part 1)

  34. Figure 23.14 The Direction of Eye Movements Can Be Altered by Electrical Stimulation in Area MT (Part 2)

  35. Figure 23.15 Area MT Microstimulation Affects a Working Memory Task

  36. Figure 23.15 Area MT Microstimulation Affects a Working Memory Task (Part 1)

  37. Figure 23.15 Area MT Microstimulation Affects a Working Memory Task (Part 2)

  38. Figure 23.16 Neuronal Representation of a Concept in Human Hippocampus

  39. Figure 23.16 Neuronal Representation of a Concept in Human Hippocampus (Part 1)

  40. Figure 23.16 Neuronal Representation of a Concept in Human Hippocampus (Part 2)

More Related