Cortical substrates of taste aversion learning: Involvement of dorsolateral amygdaloid nuclei and temporal neocortex in taste aversion learning.

Examined the involvement of the central (CE), lateral (LA), and basolateral (BL) amygdaloid nuclei and the temporal neocortices (area 20) in conditioned taste-aversion (CTA) learning. 40 adult male Long-Evans hooded rats received bilateral electrolytic lesion placements in the CE, LA, BL, or the temporal neocortices. 16 controls received scalp and meningeal incisions only. Following recovery, Ss were habituated to a restricted drinking schedule with distilled water. Animals then received CTA conditioning, with LiCl used both as the CS and as the UCS. Anterograde degeneration histologies were performed on all brain tissue to evaluate relations between CTA learning deficits and axonal pathology induced by lesion placements. Results indicate that destruction of the CE, LA, or temporal neocortex impaired CTA acquisition, but damage induced to the BL amygdaloid nucleus did not. Anatomical observations indicated that degeneration of amygdalofugal and/or corticofugal projections to the convolutions of the olfactory tubercle (medial), subthalamic nucleus, and the parabrachial complex was correlated with CTA learning deficits. Findings suggest that destruction of the dorsolateral amygdaloid nuclei and/or the temporal neocortices may produce CTA learning deficits by affecting olfactory, gustatory, and/or gastrointestinal processing in various portions of the forebrain. (51 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Cortical substrates of taste aversion learning: Dorsal prepiriform (insular) lesions disrupt taste aversion learning.

The functional relation between restricted damage to ventral primary somatosensory neocortex and the ability of rats to acquire conditioned taste aversions (CTA) was examined by a combination of behavioral and neurohistological techniques. Ss were 84 male Long-Evans hooded rats. Lesions confined exclusively to the established gustatory neocortex (GN) did not disrupt CTA acquisition, nor did lesions confined to suprarhinal cortical areas ventral to the GN. Lesions that encroached on dorsal prepiriform and insular cortices produced CTA acquisition deficits and damaged a large proportion of efferent projections to the prefrontal and precentral neocortex. Lesions of dorsal prepiriform and insular cortices did not modify taste preference–aversion thresholds to any of the 4 taste modalities. It is concluded that ventral somatosensory neocortical fields, including the established GN, do not mediate CTA acquisition and that rhinal cortices ventral and posterior to the GN are preferentially involved in associative learning for tastes and illness. (51 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Thalamocortical relations in taste aversion learning: I. Involvement of gustatory thalamocortical projections in taste aversion learning.

Examined the involvement of presumed gustatory thalamocortical projections in conditioned taste aversion (CTA) learning, using 108 male Long-Evans rats in 4 experiments. Neuroanatomical and neurobehavioral manipulations in the ventrolateral neostriatum were used. Findings demonstrate that projections from posterior ventromedial thalamic nuclei, parvicellular division (VPMpc), and thalamus to the anterior insular gustatory neocortex (AIGN) were essential for normal CTA learning. Because both VPMpc thalamus and the AIGN each have been implicated as functional substrates of CTA learning, the present results suggest that the gustatory thalamocortical relay per se is necessary for normal taste-illness learning. (40 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Thalamocortical relations in taste aversion learning: II. Involvement of the medial ventrobasal thalamic complex in taste aversion learning.

Examined the involvement of the gustatory thalamic nuclei in fundamental taste reactivity, gastrointestinal reactivity, and conditioned taste aversion (CTA) learning. In Exp I, using 72 male Long-Evans rats, bilateral electrolytic lesions were produced in the medial ventrobasal thalamic complex (VBm), including the thalamic gustatory nuclei, in 1 group of Ss. For a 2nd group, at the conclusion of conditioning, lesions were produced in the anterior insular gustatory neocortex (AIGN). Results indicate that destruction of VBm thalamus attenuated taste reactivity to sucrose, citric acid, and quinine hydrochloride. Elimination of VBm thalamus markedly attenuated CTA learning. Results of neocortical lesion manipulations showed that the AIGN contributed to initial CTA learning in Ss lacking a mediodorsal-periventricular thalamus. Whether Ss lacking VBm thalamus used olfactory cues associated with drinking solutions to acquire CTAs was evaluated in Exp II, using 72 male Long-Evans rats. Results demonstrate that Ss lacking VBm thalamus and the olfactory bulbs could not acquire aversions to ingested LiCl following 8 conditioning trials. (54 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)