S. Carlson et al., DISSOCIATION OF MNEMONIC CODING AND OTHER FUNCTIONAL NEURONAL PROCESSING IN THE MONKEY PREFRONTAL CORTEX, Journal of neurophysiology, 77(2), 1997, pp. 761-774
Single-neuron activity was recorded in the prefrontal cortex of three
monkeys during the performance of a spatial delayed alternation (DA) t
ask and during the presentation of a variety of visual, auditory, and
somatosensory stimuli. The aim was to study the relationship between m
nemonic neuronal processing and other functional neuronal responsivene
ss at the single-neuron level in the prefrontal cortex. Recordings wer
e performed in both experimental situations from 152 neurons. The majo
rity of the neurons (92%) was recorded in the prefrontal cortex. Nine
of the neurons were recorded in the dorsal bank of the anterior cingul
ate sulcus and two in the premotor cortex. Of the total number of neur
ons recorded in the prefrontal area, 32% fired in relation to the DA t
ask performance and 39% were responsive to sensory stimulation or to t
he movements of the monkey outside of the memory task context. Altoget
her 42% of the recorded neurons were neither activated by the various
stimuli nor by the DA task performance. Three types of task-related ne
uronal activity were recorded: delay related, delay and movement relat
ed, and movement related. The majority of the task-related neurons (n
= 33, 73%) fired in relation to the delay period. Of the delay-related
neurons, 26 (79%) were spatially selective. The number of spatially s
elective delay-related neurons of the whole population of recorded neu
rons was 18%. Twelve task-related neurons (27%) fired in relation to t
he response period of the DA task. Five of these neurons changed their
firing rate during the delay period and were classified as delay/move
ment-related neurons. Contrary to the delay-related neurons, less than
half (42%) of the response-related neurons were spatially selective.
The majority (70%) of the delay-related neurons could not be activated
by any of the sensory stimuli used and did not fire in relation to th
e movements of the monkey. The remaining portion of the delay-related
neurons was activated by stationary and moving visual stimuli or by vi
sual fixation of an object. In contrast to the delay-related neurons,
the majority (66%) of the task-related neurons firing in relation to t
he movement period were also responsive to sensory stimulation outside
of the task context. The majority of these neurons responded to visua
l stimulation, visual fixation of an object, or tracking eye movements
. One neuron gave a somatomotor and another a polysensory response. Th
e majority (n = 37, 67%) of all neurons responding to stimulation outs
ide of the task context did not fire in relation to the DA task perfor
mance. The majority of their responses was elicited by visual stimuli
or was related to visual fixation of an object or to eye movements. On
ly six neurons fired in relation to auditory, somatosensory, or somato
motor stimulation. This study provides further evidence about the sign
ificance of the dorsolateral prefrontal cortex in spatial working memo
ry processing. Although a considerable number of all DA task-related n
eurons responded to visual, somatosensory, and auditory stimulation or
to the movements of the monkey, most delay-related neurons engaged in
the spatial DA task did not respond to extrinsic sensory stimulation.
These results indicate that most prefrontal neurons firing selectivel
y during the delay phase of the DA task are highly specialized and pro
cess only task-related information.