Detection and discrimination of carvone enantiomers in rats with olfactory bulb lesions

Rats with lesions of dorsal and dorsolateral bulbar sites known to be differentially responsive to carvone enantiomers were tested for their ability to detect (+)-carvone, to discriminate between (+)-carvone from (-)-carvone, and to discriminate (+)-carvone from mixtures of both enantiomers after they had been pre-trained or not pre-trained on these tasks prior to surgery. In postoperative tests, rats pre-trained on the enantiomer discrimination problems made somewhat fewer errors than those not pre-trained, but experimental rats performed as well as controls (those that had one intact olfactory bulb) within both conditions and on each task. These results indicate that removal of most bulbar sites known to be differentially responsive to carvone enantiomers and the consequent disruption of normal patterns of bulbar input produced in response to carvones are largely without effect on the ability of rats to discriminate between these odors.

Olfactory marker protein immunohistochemistry and the anterograde transport of horseradish peroxidase as indices of damage to the olfactory epithelium

The present study compared the relative effectiveness of wheatgerm agglutinin--horseradish peroxidase (WGA--HRP) and olfactory marker protein (OMP) in detecting the presence of intact olfactory axons in glomeruli of the main olfactory bulb (MOB) in the rat. The olfactory epithelium was damaged by i.p. injections of the toxin 3-methyl indole and, after 5 or 6 days, the olfactory sac was injected with a 1% WGA--HRP solution. No anterograde labeling was observed in the dorsal and ventromedial quadrants of the MOB in the WGA--HRP material. However, in the same cases OMP immunostaining was observed throughout the MOB. In other rats the rostral olfactory epithelium was aspirated unilaterally and after 3, 11 and 16 days the olfactory sacs were injected with WGA--HRP and rats were perfused 1 day later. In these cases WGA--HRP reaction product was absent in the dorsolateral quadrant of the MOB on the aspirated side in all animals, but OMP immunostaining could be detected in the 4 and 12 day survival animals but not in the 17 day survival rat. These findings indicate that anterograde transport of WGA--HRP accurately reflects the presence of intact axons en route to the MOB. In contrast, OMP immunostaining persists in axon terminals severed from their parent cell body for at least 12 days and is a less useful marker of intact olfactory axons in experiments using short survival times.

Can rats acquire an olfactory learning set?

Experimental rats were trained on multiple 2-odor discrimination tasks, whereas controls were given repeated sessions on Task 1 and then were tested on a novel 2-odor task. Experimental rats showed strong positive transfer across problems and approached errorless or near-errorless learning. Control rats maintained near-perfect performance on Task 1 but performed at chance on initial trials when tested with novel odors. Thus, the near-errorless terminal performance of experimental rats was a function their having been trained on multiple problems and was not simply the result of eliminating "disruptive response tendencies" (I. C. Reid & R. G. M. Morris, 1992). Results support the view that when rats are trained on a series of 2-odor discrimination tasks, they acquire a strategy or rule that allows them to solve new problems with few or no errors.

Animal cognition and the rat olfactory system

Is smell a 'primitive' sense used primarily to guide biologically basic behaviors or might it be the sensory modality that allows some species to express complex learning and other forms of cognitive behavior? Historically, the olfactory system has been considered primitive and it is not surprising that, until recently, cognitive neuroscientists have ignored odor-guided behavior. However, we now know that the olfactory system has projections to the prefrontal cortex, entorhinal cortex and hippocampus, and that these connections support the acquisition of simple and higher-order instrumental tasks, as well as a robust memory for odors. It appears that animals with a well-developed sense of smell have the neural machinery to think with their noses.

Alterations in brain function after loss of docosahexaenoate due to dietary restriction of n-3 fatty acids

The concentration of the major polyunsaturated fatty acid (PUFA) in brain, docosahexaenoate, may be markedly reduced by two or more generations of dietary restriction of sources of n-3 fatty acids in the diet. Such a deficiency was induced through the feeding of safflower oil as the principal source of essential fatty acids. The reference point for this diet was an n-3 adequate diet to which alpha-linoleate and docosahexaenoate were added through the addition of a small quantity of flax seed or algael oils, respectively. The loss of brain DHA was associated with poorer performance in spatial tasks and an olfactory-cued reversal learning task. No difference could be observed in the hippocampal gross morphology. This study demonstrates the importance of providing a source of n-3 fatty acids during mammalian growth and development.

Can rats acquire an olfactory learning set?

Experimental rats were trained on multiple 2-odor discrimination tasks, whereas controls were given repeated sessions on Task 1 and then were tested on a novel 2-odor task. Experimental rats showed strong positive transfer across problems and approached errorless or near-errorless learning. Control rats maintained near-perfect performance on Task 1 but performed at chance on initial trials when tested with novel odors. Thus, the near-errorless terminal performance of experimental rats was a function their having been trained on multiple problems and was not simply the result of eliminating "disruptive response tendencies" (I. C. Reid & R. G. M. Morris, 1992). Results support the view that when rats are trained on a series of 2-odor discrimination tasks, they acquire a strategy or rule that allows them to solve new problems with few or no errors.

Does intranasal application of zinc sulfate produce anosmia in the rat?

Transport of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) from olfactory sensory neurons to the olfactory bulb as well as odor detection and discrimination were examined in rats in which each nasal epithelium had been irrigated with 0.1-0.5 ml 5% zinc sulfate. After treatment, rats showed few or no deficits in discriminating among odors and in detecting high (1%-0.01%) concentrations of ethyl acetate, but some had deficits in detecting lower concentrations of the odor. In most cases, HRP reaction product filled more than 30% of olfactory bulb glomeruli 2-4 days after treatment with ZnSO4. The behavioral outcomes are in agreement with recent reports of considerable savings in olfaction even after severe reduction of afferent projections to the olfactory bulb. We conclude that, in the rat, intranasal application of ZnSO4, as generally practiced, does not produce anosmia.

Decrement in the horizontal-vertical illusion: are subjects aware of their increased accuracy?

47 subjects adjusted the extended vertical lines of 20 inverted-T figures to make them appear equal to a horizontal line and rated the confidence in their accuracy after each trial. One group viewed figures of varying sizes, a second group viewed figures of standard size, and a third group viewed figures of standard size but received feedback on their accuracy immediately after completing Trial 5. Except for a significant increase in accuracy on Trial 6 for the Feedback Group, there were no differences in performance among groups. Subjects made the vertical line significantly shorter than the horizontal line on initial trials but their accuracy improved over trials. In contrast, there was no consistent increase in confidence, and several analyses indicated that confidence ratings were unrelated to accuracy. These results suggest that the subjects were unaware of the decrement in illusion that occurred over trials.

Performance of mice in an automated olfactometer: odor detection, discrimination and odor memory

Mice were trained on a variety of odor detection and discrimination tasks in 100- or 200-trial sessions using a go, no-go discrete trials operant conditioning procedure. Odors, presented for 1 s on each trial, were generated by an air dilution olfactometer (for threshold tests) and an easily constructed eight-channel liquid dilution unit (for two- and multiple-odor discrimination tasks). Mice rapidly acquired the operant task and demonstrated excellent stimulus control by odor vapors. Their absolute detection threshold for ethyl acetate was similar to that obtained with rats using similar methods. They readily acquired four separate two-odor discrimination tasks and continued to perform well when all eight odors were presented in random order in the same session and when reinforcement probability for correct responding was decreased from 1 to 0.5. Memory for these eight odors, assessed under extinction after a 32 day rest period, was essentially perfect. Time spent sampling the odor on S+ and S- trials was highly correlated with response accuracy. When accuracy was at chance levels (e.g. initial trials on a novel task), stimulus sampling time on both S+ and S- trials was approximately 0.5-0.7 s. As response accuracy increased, sampling time on S+ trials tended to increase and remain higher than sampling time on S- trials.

Olfactory function in the Red Kangaroos (Macropus rufus) assessed using odor-cued taste avoidance

Each of six kangaroos, tested in a seminatural environment. learned to respond readily to water and to sniff at but not ingest an aqueous solution of 0.1% isoamyl acetate plus 0.5% quinine. Avoidance of the odor stimulus typically occurred after licking at the solution on two to three trials for most subjects. Kangaroos also learned to avoid lower concentrations of isoamyl acetate and to discriminate between isoamyl acetate and ethyl acetate. These results are among the first to document olfactory function in kangaroos. The odor-cued taste-avoidance procedure provides a relatively simple test of olfaction that can be used in the field with open-range animals.

Olfaction and peripheral olfactory connections in methimazole-treated rats

Methimazole has been reported to produce extensive degenerative changes in olfactory epithelium and a severe deficit in odor detection [Genter BM, Owens DM, Carlone HB, Crofton KM. Fundam. Appl. Toxicol. 1996;29:71-77; Genter BM, Owens DM, Deamer NJ, Blake BL, Wesley DS, Levi PE. Toxicol. Pathol. 1995;23:477-486.]. To examine this further, rats were tested on olfactory detection and discrimination problems before and after intraperitoneal injection of 300 mg/kg methimazole. In the first 2 days after treatment, experimental rats had nasal congestion and a modest decrement on odor detection and odor mixture discrimination tasks. They performed almost as well as control rats on the third post injection day. In a separate group of rats, anterograde transport of horseradish peroxidase from olfactory epithelium to the bulb was examined 1, 2, 3, and 5 days after administration of methimazole. The treatment produced a modest but progressive disruption of bulbar input: 2 days after administration only approximately 10% of bulbar glomeruli had reduced levels of reaction product while 30-40% of glomeruli had little or no reaction product in 3-5 day survival rats. These results indicate that methimazole is not a particularly effective olfactotoxin and does not produce anosmia or even a severe hyposmia.

Selective and reversible reduction of odor sensitivity in the rat by concanavalin A

Rats were trained using an olfactometer to detect low concentrations of ethyl acetate (EA) or dimethyl disulphide vapor (DMDS). Concanavalin A (ConA) applied to the olfactory mucosa had no effect on ability of rats to detect low concentrations of EA but produced a marked deficit in detection in DMDS. DMDS detection performance returned to control levels 3 days after the ConA treatment. These results provide the first behavioral evidence for odor-specific inhibition by chemical modification of the olfactory epithelium and support the notion that ConA selectively inactivates one or more types (subclasses) of olfactory receptor proteins.

Odor detection in rats with 3-methylindole-induced reduction of sensory input

Rats were tested on odor-detection tasks after treatment with 400 mg/kg of 3-methyl-indole. As revealed by anterograde transport of horseradish peroxidase from the olfactory epithelium to the olfactory bulb glomeruli, treatment produced a severe (>97%) loss in sensory input relative to untreated controls. In almost all cases, only glomeruli in a restricted ventromedial segment of the bulb contained control levels of reaction product. In Experiment 1, five of nine experimental rats were anosmic or severely hyposmic, but the remaining four rats were able to detect amyl acetate vapor. In Experiment 2, four of seven experimental rats were anosmic, but the remaining three were able to detect each of four different odors. Among all experimental rats, those that were anosmic had significantly fewer glomeruli with dense anterograde transport than did those that could smell. Among rats that could smell, performance accuracy was related to the number of glomeruli with reaction product.

Disruption of axonal transport from olfactory epithelium by 3-methylindole

The effects of 150, 350, and 400 mg/kg intraperitoneal 3-methylindole (3-MI) on anterograde transport of horseradish peroxidase from the olfactory epithelium to the olfactory bulb were investigated. In 400 mg/kg 3-MI-treated rats sacrificed after 7 days only about 2% of all glomeruli had normal levels of the reaction product, and most glomeruli had no detectable reaction product. Lower doses of 3-MI produced correspondingly less disruption of axonal transport, with savings located primarily in the ventral to midlateral and the ventromedial region of the bulb. There was a gradual recovery of bulbar connections in 12-, 22-, and 92-day survival rats. In all cases, the increase in axonal transport was greatest in glomeruli on the lateral, ventral, and ventromedial areas of the bulb, and least evident or absent on the dorsal and dorsomedial areas.

The olfactory thalamocortical system and odor reversal learning examined using an asymmetrical lesion paradigm in rats

The olfactory thalamocortical system was disrupted bilaterally in rats using (a) unilateral mediodorsal thalamic (MD) lesions plus contralateral bulbectomy and transection of the anterior commissure (AC), (b) unilateral MD lesions plus contralateral lesions of the frontal cortex, or (c) bilateral MD lesions. Rats were trained on an odor discrimination task and on the reversal of that task. Experimental groups performed as well as controls on the initial discrimination task but made more errors on the reversal problem. Rats with asymmetrical disruption of the olfactory thalamocortical system performed as poorly as those with bilateral MD lesions. These outcomes indicate that odor reversal learning deficits in rats with bilateral MD lesions stem from interruption of the olfactory thalamic-neocortical system and also provide evidence that the AC mediates significant interhemispheric transfer of olfactory information.

The olfactory thalamocortical system and odor reversal learning examined using an asymmetrical lesion paradigm in rats

The olfactory thalamocortical system was disrupted bilaterally in rats using (a) unilateral mediodorsal thalamic (MD) lesions plus contralateral bulbectomy and transection of the anterior commissure (AC), (b) unilateral MD lesions plus contralateral lesions of the frontal cortex, or (c) bilateral MD lesions. Rats were trained on an odor discrimination task and on the reversal of that task. Experimental groups performed as well as controls on the initial discrimination task but made more errors on the reversal problem. Rats with asymmetrical disruption of the olfactory thalamocortical system performed as poorly as those with bilateral MD lesions. These outcomes indicate that odor reversal learning deficits in rats with bilateral MD lesions stem from interruption of the olfactory thalamic-neocortical system and also provide evidence that the AC mediates significant interhemispheric transfer of olfactory information.

Neuropsychologic impairment in astrocytoma survivors

Thirteen patients selected for long-term survival with primary astrocytic tumor (who failed to return to premorbid educational or vocational levels) were examined by neuropsychologic tests of specific and generalized higher cortical functions. In the absence of tumor regrowth or other neurologic disorders, each demonstrated difficulty in problem solving or coping with novel situations when previously acquired abilities, overlearned material, and psychometric intelligence appeared consistent with their premorbid level. The diffuse difficulties were unrelated to tumor type or location, and were not explicable by existing focal deficits, psychotic or depressive thought disorders, metabolic difficulties, or hydrocephalus. These examinations explained in part why these patients failed to resume active social lives or premorbid employment. The diffuse cortical dysfunction was most notable on the Category Test, Trails B, and Localization component of the Tactual Performance Test.