It is recognized that there are three components in pain, namely, sensory-discriminative, affective-motivative and cognitive-evaluative. In this study, multi-site, multi single-unit recording technique was used to simultaneously record the neuronal activities in SmI and ACC in conscious, behaving rats. The roles of SmI and ACC in pain function were investigated by comparing the responses of neuronal activities in both areas to noxious laser-heat stimulation and neuronal activity changes in fear-potentiated startle paradigm. Laser-irradiation induced a rapid, immediate pain sensation. The laser evoked potentials (LEP1 and LEP2) were recorded simultaneously from a electrode in the skull. The latencies of LEP1 and LEP2 were 67±3 ms and 356±7 ms, corresponding to previous reports. SmI units (88%) were more responsive to laser heat than ACC units (51%). Most of these responsive units were either excitatory with short-latency response (A+C0) or long-latency response (A0C+) or a combinatory response (A+C+) and there were also units inhibited by laser heat. In addition to these four patterns of responses, some ACC units had a late, long-lasting response. The ensemble responses of SmI and ACC units had two peaks. The average latencies of short-latency response and long-latency response in SmI were 52±5 ms and 368±9 ms, respectively. The average latencies of ACC neuronal response were longer, 95±11 ms and 395±23 ms, respectively. The evoked ensemble responses in SmI was stronger than in ACC. Evoked responses in SmI and ACC grew stronger with increasing intensities of stimulation. Comparing the intensity dependent change, SmI had significantly higher correlation with tail-flick ratio of the rat than that in the ACC. Indicating a better encoding ability of the SmI of the stimulation intensity than ACC. The second part of this research examined the effect of morphine on the noxious laser-heat evoked responses of SmI and ACC. Systematic administration of morphine had stronger inhibition on ACC than SmI responses. The long-latency response of SmI ensemble unit activity was reduced significantly by 5 and 10 mg/kg of morphine. However, the same dosages had no effect on SmI short-latency response. In ACC, both short-latency response and long-latency response were inhibited significantly. The third part of the research compared the response of ACC and SMI in the fear potentiated startle paradigm, in which the rat learned to associate foot-shock (US) with a visual cue (CS). The rats jumped stronger with a sudden loud noise when the noise was paired with the CS light cue. Before conditioning, there was no neuronal change in neither light-noise trials (LNT) nor noise-only trials (NT). After conditioning, 60% ACC and 52% SmI units changed their firing rates in CS presenting period of LNT. Three patterns of neuronal changes were identified, i.e., sustained-excitatory, transient-excitatory and inhibitory. On average, the changes of ACC units were stronger than SmI units. Furthermore, the amount of change of sustained-excitatory units in ACC correlated positively to the strength of startle. In comparison, there was no significant correlation between neuronal change and startle strength in SmI units. To summarize, SmI could encode the intensity of noxious heat stimulation better than ACC. ACC activity correlated better to emotional response than SmI in fear-potentiated startle paradigm. In addition, ACC noxious response was more sensitive to morphine treatment. These results suggest that SmI is more important in sensory discriminating function and ACC is more important in emotional function of pain.