The 5-HT immunoreactive innervation of the Helix procerebrum

In the procerebrum of terrestrial snails, 5-HT is a key modulatory substance of the generation of synchronous oscillatory activity and odor learning capability. In this study, we have analyzed the characteristics of the 5-HT-immunoreactive (5-HT-IR) innervation of the distinct anatomical regions of the procerebrum of Helix pomatia, applying correlative light- and electron microscopic immunocytochemistry. A dense network of 5-HT-IR innervation was demonstrated in the cell body layer, meanwhile a varicose fiber system of different density occurred in the different neuropil regions. At the ultrastructural level, labeled varicosities were found to contact both procerebral cell bodies, and different unlabeled axon profiles in the neuropils. The labeled structures established mostly close non-specialized membrane contacts with the postsynaptic profiles. The overall dense distribution of 5-HT-IR innervation supports a general modulatory role of 5-HT in processing different olfactory events.     

Recording of spontaneous oscillations in the procerebrum of terrestrial mollusk Helix in free behavior

Procerebrum is the central part of the olfactory system in terrestrial snails. Spontaneous rhythmic oscillations were described in this structure. The role of these oscillations in the mechanisms of odor perception and discrimination is unknown yet. Electrical activity of the Helix procerebrum was recorded in vivo. Changes in spontaneous rhythmic oscillations in response to olfactory stimulation were observed. Within the first 10 s after odor application (cineole) in low concentration, a statistically significant decrease in the frequency and increase in the amplitude of procerebrum oscillations were revealed in freely behaving animals. Timing of those changes corresponded to the time of defensive reaction realization of the tentacle withdrawal. The increase in the amplitude and a tendency to a decrease in the frequency of oscillations in response to odor application in high concentration were observed in time period 11-20 s, which corresponded to an increased duration of tentacle withdrawal. The results suggest an implicit relation of the amplitude and frequency of oscillations in odor perception and discrimination.     

Immunodetection and localization of nitric oxide synthase in the olfactory center of the terrestrial snail, Helix pomatia

The procerebrum of stylommatophoran snails produces nitric oxide (NO)-modulated oscillatory local field potentials which are considered the basis of olfactory information processing. Although the function of NO is well characterized in the PC, the identification and distribution of NO synthase (NOS) has not known completely. In the present study, applying a mammalian anti-NOS antibody, a 170 kDa molecular weight NOS-like protein was demonstrated in the procerebrum homogenate of Helix pomatia. NOS-like immunolabeling of the globuli cells, the internal and terminal neuropils displayed an identical distribution compared to that of NADPH-diaphorase reactive material, confirming the specificity of immunohistochemistry. The detailed characteristics of the immunostaining (different intensity of the neural perikarya, a gradual appearance in the terminal neuropil and in the axon bundles of the tentacular nerve, as well as an intense, homogeneous distribution of NOS-like immunoreactivity in the internal neuropil) suggest that NOS is expressed constitutively, maintaining a high level of the enzyme in neuropil areas. NOS accumulation in the internal neuropil suggests that NO plays an important role in delivering olfactory signals extrinsic to the procerebrum, and integrating them with other sensory modalities, respectively. Our results are the first, demonstrating unequivocally the presence of NOS and resolving its differential distribution in the Helix procerebrum.     

Neural control of olfaction and tentacle movements by serotonin and dopamine in terrestrial snail

We investigated the role of serotonin (5HT) and dopamine (DA) in the regulation of olfactory system function and odor-evoked tentacle movements in the snail Helix. Preparations of the posterior tentacle (including sensory pad, tentacular ganglion and olfactory nerve) or central ganglia with attached posterior tentacles were exposed to cineole odorant and the evoked responses were affected by prior application of 5HT or DA or their precursors 5-hydroxytryptophan (5HTP) and l-DOPA, respectively. 5HT applications decreased cineole-evoked responses recorded in the olfactory nerve and hyperpolarized the identified tentacle retractor muscle motoneuron MtC3, while DA applications led to the opposite changes. 5HTP and l-DOPA modified MtC3 activity comparable to 5HT and DA action. DA was also found to decrease the amplitude of spontaneous local field potential oscillations in the procerebrum, a central olfactory structure. In vivo studies demonstrated that injection of 5HTP in freely moving snails reduced the tentacle withdrawal response to aversive ethyl acetate odorant, whereas the injection of l-DOPA increased responses to “neutral” cineole and aversive ethyl acetate odorants. Our data suggest that 5HT and DA affect the peripheral (sensory epithelium and tentacular ganglion), the central (procerebrum), and the single motor neuron (withdrawal motoneuron MtC3) level of the snail’s nervous system.     

GABAergic effects on the slow oscillatory neural activities in the procerebrum of Limax valentianus. Short communication

We examined GABAergic modulation on "slow" oscillation (<1.0 Hz) of the procerebrum in the terrestrial mollusk, Limax valentianus. Short application of GABA-receptor agonists slightly increased the frequency of a periodic oscillation in the procerebrum, whereas persistent application decreased it. GABA-receptor antagonists decreased the oscillatory frequency. The GABA-like immunoreactivities were found in the neuropil and the cell body layers of the procerebrum. Because GABAergic inhibition is known to be essential for the generation of "fast" synchronous neuronal oscillation in the CNSs in othre many animals, our present findings are first evidence suggesting that GABA modulates 'slow' oscillation in the CNS.     

Pheromone-evoked potentials and oscillations in the antennal lobes of the sphinx moth Manduca sexta

Using intra- and extracellular recording methods, we studied the activity of pheromone-responsive projection neurons in the antennal lobe of the moth Manduca sexta. Intracellularly recorded responses of neurons to antennal stimulation with the pheromone blend characteristically included both inhibitory and excitatory stages of various strengths. To observe the activity of larger groups of neurons, we recorded responses extracellularly in the macroglomerular complex of the antennal lobe. The macroglomerular complex is part of a specialized olfactory subsystem and the site of first-order central processing of sex-pheromonal information. Odors such as the pheromone blend and host-plant (tobacco) volatiles gave rise to evoked potentials that were reproducible upon repeated antennal stimulation. Evoked potentials showed overriding high-frequency oscillations when the antenna was stimulated with the pheromone blend or with either one of the two key pheromone components. The frequency of the oscillations was in the range of 30–50 Hz. Amplitude and frequency of the oscillations varied during the response to pheromonal stimulation. Recording intracellular and extracellular activity simultaneously revealed phase-locking of action potentials to potential oscillations. The results suggest that the activity of neurons of the macroglomerular complex was temporally synchronized, potentially to strengthen the pheromone signal and to improve olfactory perception. Accepted: 19 December 1997     

Modulation of two oscillatory networks in the peripheral olfactory system by gamma-aminobutyric acid, glutamate, and acetylcholine in the terrestrial slug Limax marginatus

The digit-like extensions (the digits) of the tentacular ganglion of the terrestrial slug Limax marginatus are the cell body rich region in the primary olfactory system, and they contain primary olfactory neurons and projection neurons that send their axons to the olfactory center via the tentacular nerves. Two cell clusters (the cell masses) at the bases of the digits form the other cell body rich regions. Although the spontaneous slow oscillations and odor responses in the tentacular nerve have been studied, the origin of the oscillatory activity is unknown. In the present study, we examined the contribution of the neurons in the digits and cell masses to generation of the tentacular nerve oscillations by surgical removal from the whole tentacle preparations. Both structures contributed to the tentacular oscillations, and surgical isolation of the digits from the whole tentacle preparations still showed spontaneous oscillations. To analyze the dynamics of odor-processing circuits in the digits and tentacular ganglia, we studied the effects of gamma-aminobutyric acid, glutamate, and acetylcholine on the circuit dynamics of the oscillatory network(s) in the peripheral olfactory system. Bath or local puff application of gamma-aminobutyric acid to the cell masses decreased the tentacular nerve oscillations, whereas the bath or local puff application of glutamate and acetylcholine to the digits increased the digits' oscillations. Our results suggest the existence of two intrinsic oscillatory circuits that respond differentially to endogenous neurotransmitters in the primary olfactory system of slugs.     

Negative relationship between odor-induced spike activity and spontaneous oscillations in the primary olfactory system of the terrestrial slug Limax marginatus

Although primary olfactory systems in various animals display spontaneous oscillatory activity, its functional significance in olfactory processing has not been elucidated. The tentacular ganglion, the primary olfactory system of the terrestrial slug Limax marginatus, also displays spontaneous oscillatory activity at 1-2 Hz. In the present study, we examined the relationship between odor-evoked spike activity and spontaneous field potential oscillations in the tentacular nerve, representing the pathway from the primary olfactory system to the olfactory center. Neural activity was recorded from the tentacular nerve before, during and after application of various odors (garlic, carrot, and rat chow) to the sensory epithelium and the changes in firing rate and spontaneous oscillations were analyzed. We detected the baseline amplitude of the oscillations and baseline spike activity before stimulation. Odor stimulations for 20 s or 60 s evoked a transient increase in the firing rate followed by a decrease in the amplitude of spontaneous oscillations. The decrease in the amplitude was larger in the first 8 s of stimulation and subsequently showed recovery during stimulation. The amplitude of the recovered oscillations often fluctuated. Odor-evoked spikes appeared when the amplitude of the recovered oscillations was transiently small. These results suggest that the large oscillations could inhibit spike activity whereas the first transient increase in spike activity was followed by the decrease in the oscillation amplitude. Our results indicate that there is a significant negative correlation between spontaneous oscillations and odor-evoked spike activity, suggesting that the spontaneous oscillations contribute to the olfactory processing in slugs.     

Modulation of two oscillatory networks in the peripheral olfactory system by γ‐aminobutyric acid,glutamate, and acetylcholine in the terrestrial slug Limax marginatus

The digit‐like extensions (the digits) of the tentacular ganglion of the terrestrial slug Limax marginatus are the cell body rich region in the primary olfactory system, and they contain primary olfactory neurons and projection neurons that send their axons to the olfactory center via the tentacular nerves. Two cell clusters (the cell masses) at the bases of the digits form the other cell body rich regions. Although the spontaneous slow oscillations and odor responses in the tentacular nerve have been studied, the origin of the oscillatory activity is unknown. In the present study, we examined the contribution of the neurons in the digits and cell masses to generation of the tentacular nerve oscillations by surgical removal from the whole tentacle preparations. Both structures contributed to the tentacular oscillations, and surgical isolation of the digits from the whole tentacle preparations still showed spontaneous oscillations. To analyze the dynamics of odor‐processing circuits in the digits and tentacular ganglia, we studied the effects of γ‐aminobutyric acid, glutamate, and acetylcholine on the circuit dynamics of the oscillatory network(s) in the peripheral olfactory system. Bath or local puff application of γ‐aminobutyric acid to the cell masses decreased the tentacular nerve oscillations, whereas the bath or local puff application of glutamate and acetylcholine to the digits increased the digits' oscillations. Our results suggest the existence of two intrinsic oscillatory circuits that respond differentially to endogenous neurotransmitters in the primary olfactory system of slugs. © 2004 Wiley Periodicals, Inc. J Neurobiol 59: 304–318, 2004     

Resistance of frog olfactory bulb slow potential and afferent input inhibition to hypoxia and synaptic transmission blockade by manganese,cobalt, and magnesium ions

The effect of hypoxia and application of manganese, cobalt, and magnesium ions on electrical responses of the frog olfactory bulb to adequate stimulation and to direct electrical stimulation of the olfactory nerve were studied. The slow potential evoked by adequate stimulation and the associated inhibition of the afferent input of the olfactory bulb were found to be much more resistant to inhibition of synaptic transmission by all methods used than the postsynaptic components of the orthodromic response and associated postsynaptic inhibition. A slow potential was recorded even when synaptic transmission in the olfactory bulb was completely blocked by magnesium ions. It is concluded that the slow potential of the olfactory bulb and inhibition of its afferent input are nonsynaptic in nature. It is postulated that the slow potential reflects mainly depolarization of glial cells in the glomerular layer of the bulb evoked by accumulation of potassium ions. The possible mechanisms of inhibition of the afferent input are discussed.     

Ultrastructure of different neuropil zones of the procerebrum in snails and slugs

Ultrastructure and peculiarities of interneuronal connections in various zones of neuropil of procerebral olfactory centers of the brain in snails and slugs: in the outer and inner neuropil, zone of input of afferent fibers of labial nerves, as well as zones of running of afferent and efferent fibers of tentacular nerves, were studied. A pronounced spatial morpho-functional differentiation and a complex zonal synaptoarchitectonics of procerebrums is revealed. It has been shown that the procerebrum neural elements, both intrinsic and numerous ones coming from other brain regions and chemosensory systems, contain an enormous variety of vesicles. These vesicles provide connections between neural elements in various synapses and synapse-like junctions and in the composite divergent and convergent complexes formed by them. A positive polychemical nature of granular cells, the main neural elements of procerebrums, and functional significance of symmetric junctions predominant in procerebrums is discussed.     

Physiology and morphology of protocerebral olfactory neurons in the male moth Manduca sexta

1. We have used intracellular recording and staining with Lucifer Yellow, followed by reconstruction from serial sections, to characterize the responses and structure of olfactory neurons in the protocerebrum (PC) of the brain of the male sphinx moth Manduca sexta. 2. Many olfactory protocerebral neurons (PCNs) innervate a particular neuropil region lateral to the central body, the lateral accessory lobe (LAL), which appears to be important for processing olfactory information. 3. Each LAL is linked by its constituent neurons to the ipsilateral lateral PC, where projection neurons from the antennal lobe terminate, as well as to other regions of the PC. The LALs are also linked to each other by bilateral neurons with arborizations in each LAL. 4. Some PC neurons showed long-lasting excitation (LLE) that outlasted the olfactory stimuli by greater than or equal to 1 s, and as long as 30 s in some preparations. LLE was more frequently elicited by the sex-pheromone blend than by individual pheromone components. All bilateral neurons that showed LLE had arborizations in the LALs. LLE responses were also recorded in a single local neuron innervating the mushroom body. 5. In some other PC neurons, pheromonal stimuli elicited brief excitations that recovered to background firing rates less than 1 s after stimulation.     

Cerebral parts of chemosensory systems of the snail: Structural bases of intersensory integration

Presented are data on distribution of afferent fibers from tentacular and labial nerves innervating chemosensory tentacular organs, lips, and mouth area in the cerebral ganglia of terrestrial pulmonary snails are in the article. By using Golgi impregnation and infusion of cobalt chloride and nickel, it has been shown that most terminal branches of afferent fibers of all chemosensory organs are located in several symmetric areas of both metacerebrums. A part of fibers both of tentacular and of labial nerves form peculiar tracts and terminate in the interior neuropil of procerebrums. In metacerebrums, various neurons providing connections with afferent fibers of chemosensory organs are revealed. Many of them also innervate interior neuropil and procerebrum cell bodies area. The data obtained allow considering procerebrums as higher integrative centers of chemosensory information.     

Processing of antennular input in the brain of the spiny lobster, Panulirus argus

Neurons in the olfactory deutocerebrum of the spiny lobster, Panulirus argus, were recorded intracellularly and filled with biocytin. Recorded neurons arborized in the olfactory lobe (OL), a glomerular neuropil innervated by olfactory and some presumptive mechanosensory antennular afferents. The neurons responded to chemosensory input from the lateral antennular flagellum bearing the olfactory sensilla but not the medial flagellum bearing many non-olfactory chemosensory sensilla. Many neurons received additional mechanosensory input. Thus the OL integrates specifically olfactory with mechanosensory input. OL neurons had multiglomerular arborizations restricted to one or two of the three horizontal layers of the columnar glomeruli. OL local interneurons comprised core neurons with tree-like neurites and terminals in the base of the glomeruli and rim neurons with neurites surrounding the OL and terminals in the cap/subcap. The somata of OL local interneurons lay in the medial soma cluster (100000 somata). OL projection neurons arborized in the base of the glomeruli and ascended via the olfactory glomerular tract to the lateral protocerebrum. A parallel projection pathway is constituted by projection neurons of the accessory lobe, a glomerular neuropil without afferent innervation but intimate links to the OL. The projection neuron somata constituted the lateral soma cluster (200000 somata).Abbreviations AC anterior cluster (cluster 6,7) - AL accessory lobe - aMC anterior subcluster of medial cluster (cluster 9) - A _lNv main antenna I (antennular) nerve - A _lNM antenna I (antennular) motor nerve - A _llNv main antenna II (antennal) nerve - CB central body - CL central layer of accessory lobe - DC deutocerebral commissure - DCN deutocerebral commissure neuropil - dDUMC dorsal subcluster of dorsal unpaired median cluster (cluster 17) - dMC dorsal subcluster of medial cluster (cluster 11) - dVPALC dorsal subcluster of ventral paired anterolateral cluster (cluster 8) G glomerulus - IDUMC lateral subcluster of dorsal unpaired median cluster (cluster 16) - LC lateral cluster (cluster 10) - LF lateral flagellum of antenna I (antennule) - LL lateral layer of accessory lobe - MF medial flagellum of antenna I (antennule) - ML medial layer of accessory lobe - MPN anterior and posterior median protocerebral neuropils - OGT olfactory globular tract - OGTN olfactory globular tract neuropil - OL olfactory lobe - OLALT olfactory lobe-accessory lobe tract - PB protocerebral bridge - pMC posterior subcluster of medial cluster (cluster 9) - PT protocerebral tract - TNv tegumentary nerve - VPMC ventral paired medial cluster (cluster 12) - VUMC ventral unpaired medial cluster (cluster 13) - vVPALC ventral subcluster of ventral paired anterolateral cluster (cluster 8) - ASW artificial sea water - M3 mixture 3 - PRO L-proline - TM TetraMarin extract     

Olfactory projection neuron pathways in two species of marine Isopoda (Peracarida,Malacostraca, Crustacea)

The neuroanatomy of the olfactory pathway has been intensely studied in many representatives of Malacostraca. Nevertheless, the knowledge about bilateral olfactory integration pathways is mainly based on Decapoda. Here, we investigated the olfactory projection neuron pathway of two marine isopod species, Saduria entomon and Idotea emarginata, by lipophilic dye injections into the olfactory neuropil. We show that both arms of the olfactory globular tract form a chiasm in the center of the brain, as known from several other crustaceans. Furthermore, the olfactory projection neurons innervate both the medulla terminalis and the hemiellipsoid body of the ipsi- and the contralateral hemisphere. Both protocerebral neuropils are innervated to a comparable extent. This is reminiscent of the situation in the basal decapod taxon Dendrobranchiata. Thus, we propose that an innervation by the olfactory globular tract of both the medulla terminalis and the hemiellipsoid body is characteristic of the decapod ground pattern, but also of the ground pattern of Caridoida.     

Local interneurons and information processing in the olfactory glomeruli of the moth Manduca sexta

Intracellular recordings were made from the major neurites of local interneurons in the moth antennal lobe. Antennal nerve stimulation evoked 3 patterns of postsynaptic activity: (i) a short-latency compound excitatory postsynaptic potential that, based on electrical stimulation of the antennal nerve and stimulation of the antenna with odors, represents a monosynaptic input from olfactory afferent axons (71 out of 86 neurons), (ii) a delayed activation of firing in response to both electrical- and odor-driven input (11 neurons), and (iii) a delayed membrane hyperpolarization in response to antennal nerve input (4 neurons).Simultaneous intracellular recordings from a local interneuron with short-latency responses and a projection (output) neuron revealed unidirectional synaptic interactions between these two cell types. In 20% of the 30 pairs studied, spontaneous and current-induced spiking activity in a local interneuron correlated with hyperpolarization and suppression of firing in a projection neuron. No evidence for recurrent or feedback inhibition of projection neurons was found. Furthermore, suppression of firing in an inhibitory local interneuron led to an increase in firing in the normally quiescent projection neuron, suggesting that a disinhibitory pathway may mediate excitation in projection neurons. This is the first direct evidence of an inhibitory role for local interneurons in olfactory information processing in insects. Through different types of multisynaptic interactions with projection neurons, local interneurons help to generate and shape the output from olfactory glomeruli in the antennal lobe.Abbreviations AL antennal lobe - EPSP excitatory postsynaptic potential - GABA -aminobutyric acid - IPSP inhibitory postsynaptic potential - LN local interneuron - MGC macroglomerular complex - OB olfactory bulb - PN projection neuron - TES N-tris[hydroxymethyl]methyl-2-aminoethane-sulfonic acid     

Identification of three classes of multiglomerular,broad-spectrum neurons in the crayfish olfactory midbrain by correlated patterns of electrical activity and dendritic arborization

We recorded electrical activity from three different classes of broad-spectrum, multiglomerular neurons in the crayfish (Procambarus clarkii, P. blandingi) olfactory midbrain. Responses were obtained to odorants and electrical stimuli applied to the antennules of isolated, perfused head preparations. All three neuronal types responded to a complex mixture of five amino acids as well as to solutions of a commercial fish food. At least two classes also responded to individual amino acids and to sugars. The response properties and the morphologies of the neurons were unique to each type. Responses of Type I cells were stimulus-dependent excitatory postsynaptic potentials and superimposed impulse trains; those in Type II were stimulus-dependent inhibitory postsynaptic potentials; those in Type III were compound responses consisting of short latency hyperpolarizations, followed by depolarizing post-synaptic potentials and impulses. All three cell types had extensive, multiglomerular dendritic arbors in the olfactory lobe, but each of their respective branching pattern morphologies was distinctive. Two types had additional dendrite branches in the lateral antennular neuropil and the olfactory-globular tract neuropil. We conclude that these broad-spectrum neurons are part of a parallel olfactory pathway that is separate from the putative quality coding circuitry in the crayfish olfactory system.Abbreviations AL accessory lobe - LAN lateral antennular neuropil - OGT olfactory globular tract - OGTN olfactory globular tract neuropil - OL olfactory lobe     

Potential changes with gamma-band oscillation at the frontal scalp elicited by intravenous olfactory stimulation in humans

Intravenous olfaction is a unique stimulation method often used in Japan to diagnose olfactory disturbances. Odorant is injected into a vein and transported by blood flow and respiration to the upper air tract. The intravenous olfaction might allow the potential at the frontal scalp to be recorded without contamination from electromyograms, such as those caused by sniffing. We injected Alinamin (thiamine propyldisulphide) into healthy subjects according to a standard protocol for clinical intravenous olfaction testing and we simultaneously recorded potential changes at the frontal scalp. When Alinamin was injected into the right median cubital vein over a 20 s period, the potential changes with gamma-band oscillations were detected 17.6 +/- 6.7 s (mean +/- SD) after the start of the injection. The main frequency component of this gamma-band oscillation is 30-160 Hz. The gamma-band oscillation elicited by intravenous olfactory stimulation (VOP) was similar to the induced wave of the olfactory bulb. Mapping the VOPs on the frontal scalp of a subject with less developed frontal sinuses and the relation between the thickness of the frontal sinuses and VOP amplitude suggest an intracranial source, possibly the olfactory bulb. The gamma-band potential at the frontal scalp is a useful measure of central disturbance.     

Olfactory Evoked Potential Produced by Electrical Stimulation of the Human Olfactory Mucosa

Most physiological studies of the human olfactory system haveconcentrated on the cortical level; the olfactory bulbar levelhas been studied rarely. We attempted to stimulate the humanolfactory mucosa by electrical pulse to detect the bulbar potentials.Electrical stimulation (2 mA, 0.5 ms) of the human olfactorymucosa evoked a change in potential recorded from the frontalsector of the head. A negative peak of the evoked potentialthat occurred at 19.4 ms (grand means, n = 5) after stimulationwas the clearest. The highest amplitude of the potential wasrecorded from the frontal sector of the head on the stimulatedside. Our findings were similar to the experimental resultsobtained from the olfactory bulbs of animals. This evoked potentialwas considered to be the human olfactory bulbar potential. Whenthe subjects were stimulated by applying electricity to theolfactory mucosa, no sensation of smell occurred even thoughevoked potentials were recorded. Evoked potentials were recordedonly when the stimulating electrode was located in the olfactorycleft. When the stimulating electrode was outside the olfactorycleft, the stimulation caused pain. The trigeminal nerve seemedto be stimulated by electricity. Olfactory evoked potentialsproduced by the electrical stimulation of the human olfactorymucosa should aid the research on human olfactory physiology,and may be applicable to clinical tests of olfactory dysfunction.Chem. Senses 22: 77–81, 1997.     

Stimulus parameters and temporal evolution of the olfactory evoked potential in rats

Evoked potentials were recorded from olfactory bulb, piriformcortex and scalp in urethane anesthetized rats in response tobrief odorant stimuli (amyl acetate, phenylethyl alcohol, eugenol)presented through a nasal cannula by means of a constant flowolfactometer. The effects of stimulus duration, nasal cannulaposition, flow rate, concentration and interstimulus intervalwere examined. The highest amplitude potentials were evokedby 10% amyl acetate at 20 ms duration, 1000 ml/min flow rateand a 60-s interstimulus interval with the stimulus deliveredat the nares. Odorant evoked potentials from deep within theolfactory bulb consisted of a triphasic wave with major componentsat 60 ms (P60), 90 ms (N90) and 140 ms (P140) with the lattertwo reversing polarity close to the surface of the bulb. Potentialsrecorded from layer I of piriform cortex were of similar amplitude,but opposite in polarity to the deep olfactory bulb potentials.Recordings from the skin over the nose elicited waveforms ofsimilar morphology to the deep olfactory bulb potentials, butone-quarter the amplitude and of opposite polarity The evokedpotentials changed with repetitive stimulation The N90 componentwas not present initially and only appeared after several stimuli.The appearance of the N90 component depended on the integrityof the olfactory peduncle. Thus, olfactory evoked potentialsto odorant stimuli reflect dynamic aspects of the encoding ofolfactory information dependent on connections between olfactorybulb and piriform cortex