Event-Related Slow Potentials and Activity of Single Neurons in Rat Frontal Cortex

References

• Boyd E.H., Boyd E.S. Cortical unit activity during the M-wave and CNV in the squirrel monkey (Saimiri Sciureus). Federation Proceedings 1978; 37: 617
   Google Scholar
• Boyd E.S., Boyd E.H., Brown L.E. A cortical evoked potential that reflects the conditioned, positive incentive value of the stimulus. I. The evoked potential. Electroencephalography and Clinical Neurophysiology 1977; 42: 341–354
   Google Scholar
• Boyd E.S., Boyd E.H., Brown L.E. A cortical evoked potential that reflects the conditioned, positive incentive value of the stimulus. II. Drive motivation (hunger). Electroencephalography and Clinical Neurophysiology 1977a; 42: 355–363
   Google Scholar
• Boyd E.S., Boyd E.H., Brown L.E. A cortical evoked potential that reflects the conditioned, positive incentive value of the stimulus. III. Manipulative motivation and the value of the reward. Electroencephalography and Clinical Neurophysiology 1977b; 42: 364–371
   Google Scholar
• Boyd E.S., Boyd E.H., Brown L.E. Observations on the M-wave and the CNV in the squirrel monkey. Electroencephalography and Clinical Neurophysiology 1979; 46: 320–336
   Google Scholar
• Boyd E.S., Boyd E.H., Brown L.E. The M-wave and CNV in the squirrel monkey: Generality of cue modality and of reward. Electroencephalography and Clinical Neurophysiology 1980; 49: 66–80
   Google Scholar
• Donchin E., Otto D., Gerbrandt L.K., Pribram K.H. While a monkey waits: Electrical events recorded during the foreperiod of a reaction time study. Electroencephalography and Clinical Neurophysiology 1971; 31: 115–127
   Google Scholar
• Hablitz J.J. Operant conditioning and slow potential changes from monkey cortex. Electroencephalography and Clinical Neurophysiology 1973; 34: 399–408
   Google Scholar
• Jasper H.H., Ricci G., Doane B. Microelectrode analysis of cortical cell discharge during avoidance conditioning in the monkey. Electroencephalography and Clinical Neurophysiology 1960; 13: 137–155, Supplement
   Google Scholar
• Low M.D., Borda R.P., Kellaway P. “Contingent negative variation” in rhesus monkeys: an EEG sign of a specific mental process. Perceptual and Motor Skills 1966; 22: 443–446
   Google Scholar
• Macar F., Vitton N. Evolution of negative and positive SP shifts in cats learning RT tasks. Electroencephalography and Clinical Neurophysiology 1980; 50: 229–239
   Google Scholar
• Olds J. Multiple unit recordings from behaving rats. Bioelectric Recording Techniques Part A: Cellular Processes and Brain Potentials, R.F. Thompson, M.M. Patterson. Academic Press, Inc., New York 1973; 165–198
   Google Scholar
• Pirch J.H. Effects of amphetamine and chlorpromazine on brain slow potentials in the rat. Pharmacological Research Communications 1977; 9: 669–674
   Google Scholar
• Pirch J.H. Amphetamine effects on brain slow potentials associated with discrimination in the rat. Pharmacology, Biochemistry and Behavior 1977a; 6: 697–700
   Google Scholar
• Pirch J.H. Effects of amphetamine and pentobarbital on event-related slow potentials in rats. Multidisciplinary Perspectives in Event-Related Brain Potential Research, D. Otto. U.S. Government Printing Office, Washington, D.C. 1978; 56–60
   Google Scholar
• Pirch J.H. Event-related slow potentials in rat cortex during a reaction time task: Cortical area differences. Brain Research Bulletin 1980; 5: 199–201
   Google Scholar
• Pirch J.H. Effects of dextroamphetamine on event-related slow potentials in rat cortex during a reaction time task. Neuropharmacology 1980a; 19: 365–370
   Google Scholar
• Pirch J.H. Correlation between steady potential baseline and event-related slow potential magnitude in the rat. International Journal of Neuroscience 1980b; 11: 25–33
   Web of Science ®Google Scholar
• Pirch J.H. Event-related slow potential from rat frontal cortex in response to an auditory cue preceding electrical brain stimulation: Alteration by dextroamphetamine. Society for Neuroscience Abstracts 1980c; 6: 811
   Google Scholar
• Pirch J.H., Napier T.C., Corbus M.J. Slow potential responses from rat cortex to a single-pulse cue preceding rewarding medial forebrain bundle stimulation: Effect of amphetamine. Society for Neuroscience Abstracts, In Press
   Google Scholar
• Rebert C.S. Cortical and subcortical slow potentials in the monkey's brain during a preparatory interval. Electroencephalography and Clinical Neurophysiology 1972; 33: 389–402
   Google Scholar
• Rebert C.S., Irwin D.A. Slow potential changes in cat brain during classical appetitive conditioning of jaw movement. Electroencephalography and Clinical Neurophysiology 1969; 27: 152–161
   Google Scholar
• Rowland V. Steady potential phenomena of cortex. The Neurosciences: A Study Program, G.C. Quarton, T. Melnechuk, F.O. Schmitt. The Rockefeller University Press, New York 1967; 482–495
   Google Scholar
• Sheafor P.J., Rowland V. Dissociation of cortical steady potential shifts from mass action potentials in cats awaiting food rewards. Physiological Psychology 1974; 2: 471–480
   Google Scholar
• Skinner J.E. Abolition of a conditioned, surface-negative, cortical potential during cyrogenic blockade of the non-specific thalamocortical system. Electroencephalography and Clinical Neurophysiology 1971; 31: 197–209
   Google Scholar
• Skinner J.E. Electrogenesis of event-related slow potentials in the cerebral cortex of conscious animals. Rhythmic EEG Activities and Cortical Functioning, G. Pfurtscheller, P. Buser, F.H. Lopes da Silva, H. Petsche. Elsevier/North-Holland, Amsterdam 1980; 21–32
   Google Scholar
• Thatcher R.W., John E.R. Foundations of Cognitive Processes, Functional Neuroscience Volume I. Lawrence Erlbaum Associates, Inc., New York 1977
   Google Scholar