Relationship Between Physiological Response Type (RA and SA) and Vibrissal Receptive Field of Neurons Within the Rat Trigeminal Ganglion

doi:10.1152/jn.00157.2005

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Relationship Between Physiological Response Type (RA and SA) and Vibrissal Receptive Field of Neurons Within the Rat Trigeminal Ganglion

Steven C. Leiser¹ and Karen A. Moxon¹^,2

¹Department Neurobiology and Anatomy and ² School of Biomedical Engineering, Science and Health Systems, Drexel University, Philadelphia, Pennsylvania

Submitted 14 February 2005; accepted in final form 14 January 2006

Cells within the trigeminal ganglion (Vg) encode all the informationnecessary for the rat to differentiate tactile stimuli, yetit is the least-studied component in the rodent trigeminal somatosensorysystem. For example, extensive anatomical and electrophysiologicalinvestigations have shown clear somatotopic organization inthe higher levels of this system, including VPM thalamus andSI cortex, yet whether this conserved schemata exists in theVg is unknown. Moreover although there is recent interest inrecording from vibrissae-responsive cells in the Vg, it is surprisingto note that the locations of these cells have not even beenclearly demarcated. To address this, we recorded extracellularlyfrom 350 sensory-responsive Vg neurons in 35 Long-Evans rats.First, we determined three-dimensional locations of these cellsand found a finer detail of somatotopy than previously reported.Cells innervating dorsal facial features, even within the whiskerregion, were more dorsal than midline and ventral features.We also show more cells with caudal than rostral whisker receptivefields (RF), similar to that found in VPM and SI. Next, foreach vibrissal cell we determined its response type classifiedas either rapidly (RA) or slowly (SA) adapting. We examinedthe relationship between vibrissal RF and response type anddemonstrate similar proportions of RA and SA cells respondingto any whisker. These results suggest that if RA and SA cellsencode distinct features of stimuli, as previously suggested,then at the basic physiological level each whisker has similarabilities to encode for such features.

Address for reprint requests and other correspondence: K. A. Moxon, Drexel University, School of Biomedical Engineering, 3141 Chestnut St., Philadelphia, PA 19104 (E-mail: km57{at}drexel.edu)

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