Effects of focal inactivation of dorsal or ventral layers of the lateral geniculate nucleus on cats' ability to see and fixate small targets.

To reveal contributions of different subdivisions of the lateral geniculate nucleus (LGN) to visuomotor behavior, segments of either layer A or the C layers were inactivated with microinjections of gamma-aminobutyric acid while cats made saccades to retinally stabilized spots of light placed either in affected regions of visual space or mirror-symmetric locations in the opposite hemifield. Inactivating layer A reduced the success rate for saccades to targets presented in affected locations from 82.4 to 26.8% while having no effect on saccades to the control hemifield. Saccades to affected sites had reduced accuracy and longer initiation latency and tended to be hypometric. In contrast, inactivating C layers did not affect performance. Data from all conditions fell along the same saccade velocity/amplitude function ("main sequence"), suggesting that LGN inactivations cause localization deficits, but do not interfere with saccade dynamics. Cerebral cortex is the only target of the A layers, so behavioral decrements caused by inactivating layer A must be related to changes in cortical activity. Inactivating layer A substantially reduces the activity of large subsets of corticotectal cells in areas 17 and 18, whereas few corticotectal cells depend on C layers for visually driven activity. The parallels between these behavioral and electrophysiological data along with the central role of the superior colliculus in saccadic eye movements suggests that the corticotectal pathway is involved in both deficits and remaining capacities resulting from blockade of layer A.

Brain activation, affect, and aerobic exercise: an examination of both state-independent and state-dependent relationships.

Resting electroencephalograph (EEG) asymmetry is a biological marker of the propensity to respond affectively to, and a measure of change in affect associated with, acute aerobic exercise. This study examined the EEG-affect-exercise relationship. Twenty participants performed each of three randomly assigned 30-min conditions: (a) a nonexercise control, (b) a cycling exercise at 55% VO2max, and (c) a cycling exercise at 70% VO2max. EEG and affect were assessed pre- and 0, 5, 10, 20, and 30 min postcondition. No significant results were seen in the control or 55% conditions. In the 70% exercise condition, greater relative left frontal activation preexercise predicted increased positive affect and reduced state anxiety postexercise. Participants (n = 7) with extreme relative left frontal activation postexercise reported concomitant decreases in anxiety, whereas participants (n = 7) with extreme relative right frontal activation postexercise reported increases in anxiety. These findings (a) replicate prior work, (b) suggest a dose-response intensity effect, and (c) support the idea that exercise is an emotion-eliciting event. Affective responses seem to be mediated in part by differential resting levels of activation in the anterior brain regions. Ongoing anterior brain activation reflected concurrent postexercise affect.

Affective responses to acute exercise: a test of opponent-process theory.

Based on Solomon's Opponent-Process theory (1980), it was predicted that individuals involved in a regimen of regular aerobic exercise (active; n = 18) would respond to an acute bout of exercise with reduced negative and/or increased positive affect compared to nonactive counterparts (nonactive; n = 12). State Anxiety (SA), positive affect (PA), negative affect (NA), and self-reported fatigue were assessed immediately prior to, every 6 min during, and every 6 min following a 24 min bout of bicycle exercise performed at an RPE of 13 (+/- 1). As expected, no significant group differences occurred for RPE (M = 13.5 for nonactive, 13.2 for active). The active group did, however, exercise at a greater absolute workload than the nonactive group (261.0 +/- 22.4 W vs 200.0 +/- 19.98 W, respectively). Analyses indicated similar changes in SA and fatigue for both groups, with significant reductions in SA occurring at 6 min post-exercise and remaining below pre-exercise levels throughout the post-exercise period, while fatigue was reduced at 12, 18, and 24 min post-exercise. A significant Group x Time interaction occurred for affective valence (PA - NA; p < .01). Post hoc analyses indicated that for the active group, affect increased modestly (i.e., more PA, less NA) during exercise; this increase was sustained post-exercise. The nonactive group evidenced a sharp drop in affect (i.e., less PA, more NA) during exercise followed by a small post-exercise rise which did not return to pre-exercise levels. The results of the present study partially support the Opponent-Process model as an explanation for exercise-related affect. Although there was no differential anxiety response as a function of activity level as the model would predict, there was a differential response for affective valence in accordance with predictions.

Varying the intensity of acute exercise: implications for changes in affect.

Little is known regarding effects of components of the exercise stimulus (e.g., intensity, duration) on affective responses. The effect of varying levels of exercise intensity was examined for state anxiety (SA), positive affect (energetic arousal; EA), and negative affect (tense arousal; TA). Twenty subjects (M age = 22.6 years; M VO2 max = 47.8 ml.kg-1.min-1) participated in 3 randomly assigned conditions: (a) no exercise (control), (b) cycling@ 55% VO2max, and (c) cycling@ 70% VO2max. After being seated on an exercise bike, subjects completed the affect measures and were then told what condition they had been assigned for that day. Subjects either exercised or sat quietly on the bike for 30 min. Affect measures were obtained during exercise (or control), upon cessation of each condition, and then during the 30 min post-condition period. No changes occurred for the control condition on any variables. SA increased (p < 0.05) for both intensities during exercise followed by a significant post-exercise reduction only in the 70% VO2max condition. EA increased (p < 0.05) during exercise and remained elevated following both exercise intensities; increased EA was maintained to a greater extent following the 70% intensity condition (p < 0.05). These findings suggest that aerobic exercise (55-70% VO2max) elicits not only decreases in negative feeling states (state anxiety) but also increases in positive affect. Further, there is some evidence that such changes may be dependent on exercise intensity.