Neuronal responses to a delayed-response delayed-reward go/nogo task in the monkey posterior insular cortex.

Anatomical connections of the insular cortex suggest its involvement in cognition, emotion, memory, and behavioral manifestation. However, there have been few neurophysiological studies on the insular cortex in primates, in relation to such higher cognitive functions. In the present study, neural activity was recorded from the monkey insular cortex during performance of a delayed-response delayed-reward go/nogo task. In this task, visual stimuli indicating go or nogo responses associated with reward (reward trials) and with no reward (no-reward trials) were presented after eye fixation. In the reward trials, the monkey was required to release a button during presentation of the 2nd visual stimuli after a delay period (delay 1). Then, a juice reward was delivered after another delay (delay 2). The results indicated that the neurons responding in each epoch of the task were topographically localized within the insular cortex, consistent with the previous anatomical studies indicating topographical distributions of afferent inputs from other subcortical and cortical sensory areas. Furthermore, some insular neurons 1) nonspecifically responded to the visual cues and during fixation; 2) responded to the visual cues predicting reward and during the delay period before reward delivery; 3) responded differentially in go/nogo trials during the delay 2; and 4) responded around button manipulation. The observed patterns of insular-neuron responses and the correspondence of their topographical localization to those in previous anatomical studies suggest that the insular cortex is involved in attention- and reward-related functions and might monitor and integrate activities of other brain regions during cognition and behavioral manifestation.

Light and electron microscopic study of cholinergic and noradrenergic elements in the basolateral nucleus of the rat amygdala: evidence for interactions between the two systems.

Pharmacological studies have suggested that the cholinergic (ACh) and noradrenergic (NA) systems in the amygdala (AM) play an important role in learning and memory storage and that the two systems interact to modulate memory storage. To obtain anatomical evidence for the interaction, the organization of the ACh and NA fibers in rat AM was investigated by immunocytochemistry for choline acetyltransferase (ChAT) and dopamine-beta-hydroxylase (DBH) in conjunction with light, confocal laser scanning, and electron microscopy (LM, CLSM, and TEM, respectively). LM showed that the ChAT immunoreactivity was densest in the basolateral nucleus (BL), whereas the DBH immunoreactivity was densest in the posterior BL. CLSM demonstrated that the ChAT-immunoreactive profiles in the BL were frequently located in juxtaposition to the DBH-immunoreactive axons. The TEM observations were as follows: The majority of the synapses formed by ChAT-immunoreactive terminals were symmetric, but DBH-immunoreactive axons formed both asymmetric and symmetric synapses. The ChAT-immunoreactive terminals usually established the symmetric synaptic contacts with the DBH-immunoreactive terminals and varicosities. The DBH-immunoreactive terminals formed the asymmetric synapses with the ChAT-immunoreactive dendrites of the intrinsic neurons within the AM. The results provide anatomical substrates for mnemonic functions of the ACh and NA systems and for the interactions between the two systems in the AM.

Ameliorative effects of a cognitive enhancer, T-588, on place learning deficits induced by transient forebrain ischemia in rats.

In the present study, we investigated the effect of (1R)-1-benzo[b]thiophen-5-yl-2-[2-(diethylamino)ethoxy]ethan-1-ol hydrochloride (T-588), a newly synthesized cognitive enhancer, on place learning deficits in rats with damage selective to the hippocampal CA1 subfield induced by transient forebrain ischemia. Three weeks after the ischemic insult, T-588 was daily administered (0.3 or 3.0 mg/kg/day po). Place learning was tested in a task in which the rat was required to alternatively visit two places located diametrically opposite each other in an open field. The ischemic rats without the treatment of T-588 displayed severe learning impairment in this task; their performance level was significantly inferior to that of the sham-operated rats. The treatment of T-588 improved dose-dependently the task performance in ischemic rats, although no apparent protective effects on ischemic damage were found histologically. These results suggested that T-588 has ameliorative effects on learning deficits induced by brain ischemia, which could be produced through enhancement of residual cognitive functions.

Retrospective and prospective coding for predicted reward in the sensory thalamus.

Reward is important for shaping goal-directed behaviour. After stimulus-reward associative learning, an organism can assess the motivational value of the incoming stimuli on the basis of past experience (retrospective processing), and predict forthcoming rewarding events (prospective processing). The traditional role of the sensory thalamus is to relay current sensory information to cortex. Here we find that non-primary thalamic neurons respond to reward-related events in two ways. The early, phasic responses occurred shortly after the onset of the stimuli and depended on the sensory modality. Their magnitudes resisted extinction and correlated with the learning experience. The late responses gradually increased during the cue and delay periods, and peaked just before delivery of the reward. These responses were independent of sensory modality and were modulated by the value and timing of the reward. These observations provide new evidence that single thalamic neurons can code for the acquired significance of sensory stimuli in the early responses (retrospective coding) and predict upcoming reward value in the late responses (prospective coding).

Effect of immunity on gene delivery into anterior horn motor neurons by live attenuated herpes simplex virus vector.

Efficient and prolonged foreign gene expression has been demonstrated in the bilateral anterior horn motor neurons of the spinal cord by intramuscular inoculation with attenuated herpes simplex virus (HSV) expressing latency associated transcript promoter-driven beta-galactosidase (betaH1). To examine the effect of immunity on the gene delivery, betaH1 was applied in rats immunized subcutaneously or intramuscularly with the parent HF strain. Rats were immunized subcutaneously with HF strain and 28 days later when the high antibody titer was maintained, betaH1 was inoculated into the right gastrocnemius muscle. Second, 35 days after inoculation with HF strain into the right gastrocnemius muscle, betaH1 was inoculated at the same site. In both ways of immunization, immunity did not abolish or prevent the transgene expression in the anterior horn motor neurons, but attenuated the range and the number of the beta-galactosidase-positive neurons from about 85% to 50-65% on 28 days after inoculation with betaH1. However, beta-galactosidase activity was observed in a wide range of the bilateral anterior horn motor neurons without significant pathological changes. These findings support the feasibility of the attenuated HSV vector in gene delivery into the central nervous system, even in the presence of immunity.

Red ginseng ameliorated place navigation deficits in young rats with hippocampal lesions and aged rats.

Effects of hippocampal lesions and aging on spatial learning and memory and ameliorating effects of red ginseng on learning deficits were investigated in the following two experiments: performance of young rats with selective hippocampal lesions with red ginseng by mouth (p.o.; Experiment 1) and aged rats with red ginseng (p.o.; Experiment 2) in the spatial tasks was compared with that of sham-operated or intact young rats. Each rat in these two behavioral experiments was tested with the three types of spatial-learning tasks (distance movement task, DMT; random-reward place search task, RRPST; and place-learning task, PLT) in a circular open field using intracranial self-stimulation as reward. The results in the DMT and RRPST tasks indicated that motivational and motor activity of young rats with hippocampal lesions with and without ginseng were not significantly different from that of sham-operated young rats in Experiment 1. However, young rats with hippocampal lesions displayed significant deficits in the PLT task. Treatment with red ginseng significantly ameliorated place-navigation deficits in young rats with hippocampal lesions on the PLT task. Similarly, red ginseng improved performance of aged rats on the PLT task in Experiment 2. The results, along with previous studies showing significant effects of red ginseng on the central nervous system, suggest that red ginseng ameliorates learning and memory deficits through effects on the central nervous system, partly through effects on the hippocampal formation.

Long-term gene expression in the anterior horn motor neurons after intramuscular inoculation of a live herpes simplex virus vector.

To clarify the feasibility of the herpes simplex virus (HSV) vector in expressing the foreign gene in the motor neuron, we inoculated a live attenuated HSV expressing beta-galactosidase (beta-gal) activity under a latency-associated transcript promoter in the right gastrocnemius muscle of rats. Expression of beta-gal activity was observed 5 days after inoculation in the bilateral anterior horn cells of the spinal cord that innervates the inoculation muscle. However, the spread of beta-gal activity was not observed in the inoculation muscle. Without significant pathological changes, the spread of beta-gal-expressing neurons was observed in the lumbosacral spinal cord until 14 days after inoculation with staining concentrated in the anterior horn cells. Ninety percent of the anterior horn motor neurons expressed beta-gal activity with expression continuing to at least 182 days after inoculation. Thus beta-gal activity was expressed in the bilateral anterior horn cells at the lumbosacral spinal cord that innervates the inoculated muscle for a long time, possibly a life-long period. This indicates that this recombinant HSV vector system to motor neurons may further improve the understanding and treatment of neurological diseases in motor neurons of the spinal cord.

Hypothalamic and amygdalar neuronal responses to various tastant solutions during ingestive behavior in rats.

The forebrain, including the amygdala (AM) and hypothalamus, may be a higher brain center that modulates the activity of a brainstem neural system that influences ingestive behavior via descending projections. In this study, to elucidate the characteristics of sensory information processing in the forebrain in relation to this putative connection, we recorded neuronal activity in the AM and hypothalamus [lateral hypothalamic area (LHA), medial hypothalamic area (MHA)] of rats during discrimination of conditioned sensory stimuli and the ingestion of various tastant solutions. Of 420 responsive AM neurons identified, 24 were taste responsive and located mainly in the central nucleus of the AM. Multivariate analyses of these taste neurons suggested that in the AM, taste quality is processed on the basis of palatability. In the hypothalamus, of 282 LHA and MHA neurons recorded, 144 responded to one or more conditioned auditory stimuli and/or licking of one or more solutions. Stress, which is known to influence feeding behavior, increased the mean spontaneous activity of LHA neurons but decreased the mean spontaneous neuronal activity of MHA neurons. This pattern of changes in spontaneous neuronal activity correlated with alterations in feeding behavior during stress. Furthermore, the activity of both AM and LHA neurons was modulated flexibly during conditioned associative learning. Together, the data suggest that the activity of the AM and hypothalamic neurons is altered when animals must modulate ingestive behavior by learning a new stimulus associated with food and by being exposed to stress, suggesting that these forebrain areas are important modulators of the activity of a basic neural system in the brainstem that influences ingestive behavior.

Orbital cortex neuronal responses during an odor-based conditioned associative task in rats.

Neuronal activity in the rat orbital cortex during discrimination of various odors [five volatile organic compounds (acetophenone, isoamyl acetate, cyclohexanone, p-cymene and 1,8-cineole), and food- and cosmetic-related odorants (black pepper, cheese, rose and perfume)] and other conditioned sensory stimuli (tones, light and air puff) was recorded and compared with behavioral responses to the same odors (black pepper, cheese, rose and perfume). In a neurophysiological study, the rats were trained to lick a spout that protruded close to its mouth to obtain sucrose or intracranial self-stimulation reward after presentation of conditioned stimuli. Of 150 orbital cortex neurons recorded during the task, 65 responded to one or more types of sensory stimuli. Of these, 73.8% (48/65) responded during presentation of an odor. Although the mean breadth of responsiveness (entropy) of the olfactory neurons based on the responses to five volatile organic compounds and air (control) was rather high (0.795), these stimuli were well discriminated in an odor space resulting from multidimensional scaling using Pearson's correlation coefficients between the stimuli. In a behavioral study, a rat was housed in an equilateral octagonal cage, with free access to food and choice among eight levers, four of which elicited only water (no odor, controls), and four of which elicited both water and one of four odors (black pepper, cheese, rose or perfume). Lever presses for each odor and control were counted. Distributions of these five stimuli (four odors and air) in an odor space derived from the multidimensional scaling using Pearson's correlation coefficients based on behavioral responses were very similar to those based on neuronal responses to the same five stimuli. Furthermore, Pearson's correlation coefficients between the same five stimuli based on the neuronal responses and those based on behavioral responses were significantly correlated. The results demonstrated a pivotal role of the rat orbital cortex in olfactory sensory processing and suggest that the orbital cortex is important in the manifestation of various motivated behaviors of the animals, including odor-guided motivational behaviors (odor preference).

Emotional and behavioral correlates of the anterior cingulate cortex during associative learning in rats.

Neuronal activity was recorded from the anterior cingulate cortex of behaving rats during discrimination and learning of conditioned stimuli associated with or without reinforcements. The rats were trained to lick a protruding spout just after a conditioned stimulus to obtain reward (intracranial self-stimulation or sucrose solution) or to avoid aversion. The conditioned stimuli included both elemental (auditory or visual stimuli) and configural (simultaneous presentation of auditory and visual stimuli predicting reward outcome opposite to that predicted by each stimulus presented alone) stimuli. Of the 62 anterior cingulate neurons responding during the task, 38 and four responded differentially and non-differentially to the conditioned stimuli (conditioned stimulus-related neurons), respectively. Of the 38 differential conditioned stimulus-related neurons, 33 displayed excitatory (n = 10) and inhibitory (n = 23) responses selectively to the conditioned stimuli predicting reward. These excitatory and inhibitory differential conditioned stimulus-related neurons were located mainly in the cingulate cortex areas 1 and 3 of the rostral and ventral parts of the anterior cingulate cortex, respectively. The remaining 20 neurons responded mainly during intracranial self-stimulation and/or ingestion of sucrose (ingestion/intracranial self-stimulation-related neurons). Increase in activity of the ingestion/intracranial self-stimulation-related neurons was correlated to the first lick to obtain rewards during the task, suggesting that the activity reflected some aspects of motor functions for learned instrumental behaviors. These ingestion/intracranial self-stimulation-related neurons were located sparsely in cingulate cortex area 1 of the rostral part of the anterior cingulate cortex and densely in frontal area 2 of the caudal and dorsal parts of the anterior cingulate cortex. Analysis by the multidimensional scaling of responses of 38 differential conditioned stimulus-related neurons indicated that the anterior cingulate cortex categorized the conditioned stimuli into three groups based on reward contingency, regardless of the physical characteristics of the stimuli, in a two-dimensional space; the three conditioned (two elemental and one configural) stimuli predicting sucrose solution, the three conditioned (two elemental and one configural) stimuli predicting no reward, and the lone conditioned stimulus predicting intracranial self-stimulation. The results suggest that the anterior cingulate cortex is organized topographically; stimulus attributes predicting reward or no reward are represented in the rostral and ventral parts of the anterior cingulate cortex, while the caudal and dorsal parts of the anterior cingulate cortex are related to execution of learned instrumental behaviors. These results are in line with recent neuropsychological studies suggesting that the rostral part of the anterior cingulate cortex plays a crucial role in socio-emotional behaviors by assigning a positive or negative value to future outcomes.

Gustatory and multimodal neuronal responses in the amygdala during licking and discrimination of sensory stimuli in awake rats.

The amygdala (AM) receives information from various sensory modalities via the neocortex and directly from the thalamus and brain stem and plays an important role in ingestive behaviors. In the present study, neuronal activity was recorded in the AM and amygdalostriatal transition area of rats during discrimination of conditioned sensory stimuli and ingestion of sapid solutions. Of the 420 responsive neurons, 227 responded exclusively to one sensory modality, 120 responded to two or more modalities, and the remaining 73 could not be classified. Among the responsive neurons, 108 responded to oral-sensory stimulation (oral-sensory neurons). In detailed analyses of 84 of these oral-sensory neurons, 24 were classified as taste responsive and were located mainly in the central nucleus of the AM. The other 60 oral-sensory neurons were classified as nontaste oral-sensory neurons and were distributed widely throughout the AM. Both the taste and nontaste oral-sensory neurons also responded to other sensory stimuli. Of the 24 taste neurons, 21 were tested at least with four standard taste solutions. On the basis of the magnitudes of their responses to these sapid stimuli, the taste neurons were classified as follows: seven sucrose-best, four NaCl-best, three citric acid-best, and six quinine HCl-best. The remaining cell responded significantly only to lysine HCl and monosodium glutamate. Multivariate analyses of these 21 taste neurons suggested that, in the AM, taste quality was processed based on palatability. Taken with previous lesion studies, the present results suggest that the AM plays a role in the evaluation of taste palatability and in the association of taste stimuli with other sensory stimuli.

Single neuron responses in the monkey anterior cingulate cortex during visual discrimination.

Single neuron activity was recorded from the monkey anterior cingulate cortex during operant behavior based on discrimination of rewarding, aversive, and neutral objects. Of 550 neurons recorded, 116 responded during the task; 36, during visual discrimination; 40, during bar pressing for operant responding. Of these, 26 vision-related neurons responded differentially to rewarding, aversive and neutral objects, and 11 bar press-related neurons differentiated bar pressing to avoid shock from bar pressing to obtain reward. Responses of these neurons depended on associative meaning (aversive or rewarding) of the objects since these neuronal responses were modulated by the reversal learning. The results provide neuronal bases for involvement of the anterior cingulate cortex in emotional and motivational processes.

Detection of the circulating lung cancer marker LCAP with a new monoclonal antibody TRD-L1.

Lung Cancer Associated Protein (LCAP) is a high molecular weight glycoprotein defined by the monoclonal antibody (MAb) DF-L1 prepared against a primary adenocarcinoma of the lung. Previous studies have demonstrated that LCAP circulates at elevated levels in patients with lung cancer. However, a suitable assay for monitoring LCAP levels has not been available. The present work describes the development of a double-determinant LCAP assay using MAb TRD-L1 as the capture antibody and MAb DF-L1 as the tracer. In 60 normal subjects, the mean LCAP level was 4.8 U/ml with 2 (3.3%) subjects having values > 12 U/ml (mean + 2SDS). By contrast, 37 of 67 (55.2%) patients with lung cancer had LCAP levels > 12 U/ml. Moreover, only 14 of 203 (6.9%) patients with benign lung disease had elevated levels. LCAP levels were most commonly elevated (62.7%) in patients with adenocarcinoma of the lung and with advanced disease. These results indicate that LCAP as detected by MAb TRD-L1 is a potentially useful marker for the evaluation of patients with lung cancer.

Septal neuronal responses related to spatial representation in monkeys.

Neuronal activity in the monkey septal nuclei was recorded during performance of a place-dependent go/no-go task in which reward contingencies of the objects were variable with reference to the spatial location of a monkey's cab in one of four places in an experimental room. Of 430 septal neurons recorded, 58 responded differentially to views outside the cab at the four locations of the monkey (place-differential neurons). To investigate the possibility that an ensemble of place-differential neurons represents a space by encoding different scenes (views), responses of the 58 place-differential neurons were analyzed by multidimensional scaling (MDS). The MDS transformed relationships among the four places, expressed as correlation coefficients between all possible pairs of two places based on the 58 place-differential responses, into geometrical relationships in a two-dimensional virtual space. The four places distributed at relative positions in a two-dimensional virtual space derived from the MDS were similar to those in the real experimental room. Furthermore, these correlation coefficients derived from 58 place-differential responses significantly and negatively correlated to behavioral performance in the discrimination of the four places. The results suggest that the ensemble of place-differential responses in the septal nuclei may predict behavioral performance to discriminate places and may represent a space based on the scenes viewed from different locations.

Contribution of chorda tympani and glossopharyngeal nerves to taste preferences of rat for amino acids and NaCl.

To learn how the gustatory nerves convey information about the nutritionally dependent taste preference, intake of amino acid solutions and saline in rats with bilateral chorda tympani (CTX) and/or glossopharyngeal neurotomy (GPX) was determined during the feeding of a control diet (C) and a L-lysine (Lys) deficient diet (LD). Intact rats preferred L-arginine (Arg) more in C and Lys more in LD. The CTX group did not select nor ingest Lys in LD, and its intake of Arg was also low in C. The GPX group did not substantially alter its preference under both diets, while it did show an increase in total liquid intake. The preference changes in the CTX + GPX group appeared as combined effects of the CTX and the GPX groups. In an additional study, the preference for Lys shifted to higher concentrations and the total consumption of Lys increased in LD. The present data suggest that the chorda tympani nerves possibly function as discriminators of the nutritional information by altering the taste preference, and that the glossopharyngeal nerves may convey other functional taste information, such as aversive tastes, and sensory aspects of osmotic regulation. In addition, it is revealed that the animals have ability to search for a nutrient deficient in their body, and to ingest it to a level that at least nullifies the deficiency.

Neuronal responsiveness to various sensory stimuli, and associative learning in the rat amygdala.

Neuronal activities were recorded from the amygdala and amygdalostriatal transition area of behaving rats during discrimination of conditioned auditory, visual, olfactory, and somatosensory stimuli associated with positive and/or negative reinforcements. Neurons were also tested with taste solution and various sensory stimuli that were not associated with reinforcement. Of the 1195 neurons tested, 475 responded to one or more sensory stimuli. Of these, 256 neurons responded exclusively to a unimodal sensory stimulus, 128 to multimodal sensory stimuli, and the remaining 91 could not be classified. Distribution of unimodal neurons was correlated with anatomical projections to the amygdala from sensory thalamus or sensory cortices. Multimodal neurons were located mainly in the basolateral and central nuclei of the amgydala. Response latencies of neurons in the basolateral nucleus were longer than those in other nuclei and neurons in the central nucleus had both short and long latencies. Neurons responsive to a given stimulus were more frequently encountered in the amygdalas of the trained rats than in those of the rats not trained to associate that stimulus with a reinforcement. Multimodal neurons that responded to conditioned and/or unconditioned stimuli used in the associative learned tasks were concentrated in the basolateral and central nuclei. The results indicate that some amygdalar neurons receive exclusive single sensory information, and the others receive information from two or more sensory inputs. Considering the long latencies and multimodal responsiveness, the basolateral and central nuclei of the amygdala might be foci where various kinds of sensory information converge. It is also suggested that the basolateral and central nuclei of the amygdala have critical roles in associative learning to relate sensory information to reinforcement or affective significance.

Amygdala role in conditioned associative learning.

Amygdala role in emotion was reviewed in reference to recent amygdala lesion studies and neuronal responses in the rat amygdala to conditioned stimuli. Extensive lesion studies suggest that the amygdala is crucial in various kinds of motivated and emotional behavior, and related autonomic responses. These amygdala functions critically depend on learning and memory. Amygdala lesions, both before and after training of conditioned associative learning, impaired emotional expression without simple sensory-motor deficits. Pharmacological experiments indicated neurotransmission in the amygdala is mediated through NMDA and AMPA receptors. These results strongly suggest the amygdala involvement in acquiring and storing associative memory (i.e. stimulus-affect association), by which animals recognize and evaluate the biological significance of a stimulus. This information is then transferred to the brainstem executing system. In the neurophysiological experiments, there were topographic distributions of sensory-responsive neurons within the amygdala, which were well correlated to anatomical data. The responses of rat amygdala neurons changed plastically during learning. Furthermore, more sensory-responsive neurons were encountered in the amygdala of rats trained to associate the sensory stimuli with a reinforcement than in the amygdala of rats that were not trained. In trained rats, multimodal neurons that responded to conditioned and unconditioned stimuli were frequently found in the basolateral and central nuclei of the amygdala. The results suggest that basolateral and central nuclei are foci where various sensory modalities converge, and which might perform critical functions in acquiring and storing long-term associative memory to link between sensory information and affective significance.

Reciprocal IL-1 beta gene expression in medial and lateral hypothalamic areas in SART-stressed mice.

Specific alteration of rhythm of temperature (SART) stress has been found to induce thymic atrophy via activation of the hypothalamus-pituitary-adrenal (HPA) axis. We demonstrate here that SART stress induces increment of IL-1 beta mRNA levels in the medial hypothalamic area (MHA) and decrement of IL-1 beta mRNA levels in the lateral hypothalamic area (LHA). The altered levels of IL-1 beta expression in these loci return to those of non-stressed mice upon cessation of the stress. These data imply that the reciprocal wave of SART stress-induced IL-1 beta gene expression in MHA and LHA may contribute to activation of the HPA axis and the resulting immunological dysfunction.

The structure-activity relationship between phenylene-polymethylene bis-ammonium derivatives and their neuromuscular blocking action on mouse phrenic nerve-diaphragm muscle.

The structure-activity relationship of phenylene-polymethylene bis-ammonium (PMBA) derivatives, C6H4[X(CH2)nR]2, on isolated mouse phrenic nerve-diaphragm muscle was investigated to obtain more potent and stable compounds for use as pharmacological tools to clarify the mechanism of succinylcholine (SuCh)-induced neuromuscular blockade. The neuromuscular blocking effect of all the PMBA derivatives was not reversed by neostigmine, a cholinesterase inhibitor. The potency of the neuromuscular blockade was in the order p- > o- > m- with respect to the side-chain substituents. A PMBA composed of X = CH2, n = 5 and R = N+Et3 was 5.9- and 23-fold more potent than SuCh and decamethonium, respectively. The derivatives of R = N+Et3 were observed to be more potent than those of R = N+Me3, N-Me-piperidinio and pyridinio derivatives. Replacement of X = CH2 with O, CHOH and CHOAc decreased the neuromuscular activity while replacement with S, SO and SO2 increased it. Introduction of NO2 into the phenylene ring increased the activity, while the introduction of an alcohol, aldehyde and ketone group decreased it. Removal of a carbonyl or ether group from SuCh decreased its activity, whereas the introduction of these into PMBA failed to increase it. We managed to synthesize unhydrolyzable neuromuscular blocking agents which are more potent than SuCh.

Different modes of potentiation by beta-eudesmol, a main compound from Atractylodes lancea, depending on neuromuscular blocking actions of p-phenylene-polymethylene bis-ammonium derivatives in isolated phrenic nerve-diaphragm muscles of normal and alloxan-diabetic mice.

The essential moieties in p-phenylene-polymethylene bis-ammonium (PMBA) derivatives, C6H4[X(CH2)nN+R3]2, on the potentiating effects by beta-eudesmol, a main component of Atractylodes lancea, of their neuromuscular blockades were investigated in isolated phrenic nerve-diaphragm muscle preparations of normal and alloxan-diabetic mice. PMBA derivatives were separated into the following three groups based on the patterns of the potentiating effects: group I: PMBA-23 (n = 6, R = Me) and PMBA-24 (n = 6, R = Et); group II: PMBA-1 (n = 4, R = Me), PMBA-21 (n = 4, R = Et) and PMBA-2 (X = O, n = 3, R = Me); and group III: PMBA-31 (X = S, n = 3, R = Me), PMBA-3 (X = CO, n = 3, R = Me) and PMBA-4 (X = CHOH, n = 3, R = Me). The pretreatment with 80 microM beta-eudesmol for 60 min did not affect group I-induced neuromuscular blocking action, and it potentiated group II- and group III-induced ones. The potentiating effect of beta-eudesmol on group III was greater in diabetic muscles than in normal one and that on group II was to the same extent in both muscles. These results suggest that the four-methylene length of the side chains in normal muscles and the hydrophilic moieties adjacent to a phenylene ring in diabetic muscles are related to the potentiating effect by beta-eudesmol on PMBA derivatives.