Some electron microscope findings of the claustrum of the cat

The properties of the giant cerebral serotonin-containing neurons of the opisthobranch mollusc Aplysia californica were studied and were compared to the existing data on the giant serotonin-containing neurons (metacerebral cells) of pulmonate mulluscs. Among the properties examined were: axonal distribution, synaptic input and output, pharmacological responses, biophysical characteristics, and plasticity. With only minor exceptions, the properties of the serotonin-containing neurons of Aplysia and of pulmonate molluscs were remarkably similar, and it was concluded that these identified neurons are true homologues. The establishment of the homology of the metacerebral cells of Aplysia to the metacerebral cells of pulmonate molluscs extends the known distribution of these neurons to a second major subclass (Opisthobranchiata) of molluscs. Since pulmonate and opisthobranch molluscs differ substantially in behavioral and anatomical features, the study of the metacerebral cells of these two groups may promote the understanding of the evolutionary adaptation of the nervous system to different environmental pressures.     

Immunoreactivity for calcium-binding proteins in the claustrum of the monkey

The sequence of degenerative changes in the retinal pigment epithelium (RPE) and the choroid of retinal degeneration (rd)-mice was studied in correlation with photoreceptor changes. Three weeks to 26-month-old animals were investigated using light and transmission electron microscopy, enzyme histochemistry and quantitative morphology. Changes in the choriocapillaris (CC) were additionally studied by scanning electron microscopy of corrosion cast preparations. In 3-week-old mice, in which most of the outer segments of photoreceptors in the central portion of the retina had disappeared but remnants of the cells were still present, the RPE was enlarged and showed elongated microvilli. In 8-week-old animals, the photoreceptors were completely absent in large areas of the posterior pole region. In these areas the RPE was also completely lost. Quantitative evaluation performed in histological serial sections showed that loss of RPE measured as length of RPE-free Bruch's membrane, continuously increased up to the age of 20 months. In 8-week-old animals, CC adjacent to degenerating RPE showed loss of fenestration. In 10-week-old animals, the CC disappeared in those areas where the RPE was already lacking. The loss of CC increased with increasing age and in 20-month-old animals 5-10% of the entire CC was lacking. Loss of the related arterioles and nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d)-positive nerve fibers occurred only in approximately 2-year-old rd-mice. Compared to other animal models, RPE and CC defects in rd-mice are relatively large. The rd-mice might therefore provide a good tool to study factors involved in CC degeneration.     

Contribution of mechanical activity and electrical activity to cellular electrical uncoupling in ischemic rabbit papillary muscle

We separated mechanical and electrical activity during ischemia and we assessed the contribution of each of these variables to ischemia induced cellular electrical uncoupling. In two groups of rabbit papillary muscles, mechanical and electrical activity at the onset of ischemia was abolished. We determined how this affected the time of onset of uncoupling. Also, action potential duration (APD80), conduction velocity and extracellular pH were recorded. In the first group, the BDM group, mechanical arrest was achieved with 10 mM BDM (2,3-butanedione monoxime). This had no effect on APD80 and conduction velocity. In the second group, the quiescent group, electrical as well as mechanical arrest was obtained by not stimulating the muscles. The effect of electrical arrest was estimated as the difference between this group and the BDM group. Mechanical arrest delayed uncoupling significantly (control: 14.6 +/- 0.9 (min), mean +/- S.E.M., n = 10; BDM: 19.3 +/- 1.1, n = 10; P < 0.025). Electrical arrest caused an even greater delay (quiescent: 41.6 +/- 4.6, n = 7; P < 0.001 v control and BDM). In the BDM group, these effects were not associated with a difference of APD80 during ischemia, but with a smaller decrease of conduction velocity. Delay of uncoupling correlated with delay of extracellular acidosis. We conclude: (1) mechanical and electrical activity both are significant determinants of ischemia induced uncoupling; (2) delay of uncoupling is associated with delay of extracellular acidosis, indicating a reduced rate of metabolism.     

Hypothalmic influences on the electrical activity of the olfactory pathway

The cycle of events which leads to an impairment of the immune response in the malnourished child includes poverty, food deprivation and frequent infections. It is of great significance, however, that the marked suppression of the immune response can be repaired reasonably promptly, if the disease commences after the child has attained 1 year of age. Prenatal infection not only generates growth retardation but also a higher maternal to foetal IgG ratio, higher IgM in the neonate and a sustained immune depression. Passive cutaneous anaphylaxis measurements in the baboon skin and specific IgE determinations reveal that the elevated IgE in PEM is due to parasitic infestation and common allergens and has little or no relationship with decreased T-cell function.     

Comparative anatomy of the claustrum in selected species: A morphometric analysis

The morphology of the claustrum was studied by stereological methods in representatives of five mammalian orders (Insectivora, Rodentia, Lagomorpha, Carnivora and Primates). In each species under study, a dorsal and a ventral part of the nucleus can be distinguished. Based on differences in shape and separation from surrounding structures, five morphological types of the claustrum occur. The claustrum of Insectivora and some rodents represents the least complicated morphological type. The nucleus is very poorly separated from the surrounding structures. The human claustrum is morphologically the most complicated, although the two above-mentioned principal divisions are apparent. The ventrally situated paraamygdalar part of the human claustrum may correspond to the endopiriform nucleus or ventral part of the claustrum of other mammals, because of its morphological characteristics and connections with the limbic system. In guinea pigs, traditionally classified as members of the Rodentia, a characteristic morphological type of the claustrum is present. This observation may support arguments questioning the current position of this species in mammalian classification. Based on stereological studies, the increase of the claustral volume that occurs with increase of the hemispheric volume is significantly smaller than the increase of the isocortical volume and larger than the increase of the allocortical volume. The increase of the volume of the dorsal and ventral parts of the claustrum does not differ significantly in the species under study. Neurons of the claustrum represent differentiated morphology. The numerical density of neurons in the dorsal part of the claustrum is significantly higher than in the ventral one. Differences in the morphology and cellular structure of the two parts of the claustrum may suggest differences in function of the two parts of the nucleus, most probably concerned with transfer of information among various cortical regions. Changes in the claustrum, a cortico-related structure, that occur with increased brain volume, may suggest that its development is less dynamic than that of the isocortex.     

Division of the human claustrum according to its architectonics and morphometric parameters

The topography and cytoarchitectonics of the claustrum as well as morphometric parameters of its neurons were studied in 10 human brains obtained from patients without any detectable neuropathological changes. We distinguished four parts of the claustrum: dorsal, orbital, temporal and paraamygdalar. The dorsal and orbital parts contain larger cells, than those of the temporal and paraamygdalar parts, although these differences were statistically non significant. The highest neuronal density was observed in the paraamygdalar part. The nucleus and nucleus@cell body area ratio was significantly smaller in the dorsal part than in other parts of the claustrum. We described three types of neurons in the claustrum: (1) medium-sized either fusiform or triangular cells with darkly stained cytoplasm; they predominate in the dorsal and temporal parts, (2) medium-sized as well as large cells, either multipolar or pyramidal-like with lightly stained cytoplasm; they are most numerous in the orbital and paraamygdalar parts, (3) small, multipolar or oval neurons with darkly stained ring of cytoplasm; these types of neurons are uniformly distributed throughout all parts of the claustrum. The subdivision of the human claustrum is in accordance with our observations that each of these parts possesses connections with different cortical regions.     

Postprandial changes of electrical activity of the stomach after different meals

AIM: The aim of the study was to investigate the response of the electrical activity of the stomach (electrogastrogram, EGG) to meals, different with respect to consistency, nutrient and caloric composition. METHODS: EGG was recorded in ten healthy volunteers for 30 min before and 45 min after a meal. All subjects received three different meals: A standard 500 kcal solid, a 500 cc isocaloric liquid diet of identical composition (55% carbohydrates, 15% protein, 30% fat) or 500 cc water. Data were analyzed off-line for postprandial changes. RESULTS: Water as well as liquid diet induced a significant postprandial decrease, while solid food induced a slight initial decrease and a subsequent marked increase of the dominant frequency above the fasting level. The response to the solid meal was significantly different from both tap water and liquid diet, but there was no difference between liquid diet and water. All meals significantly increased the signal power with a more sustained effect over time for the liquid diet and water than the solid meal. CONCLUSION: EGG changes seem to be more dependent on the consistency than the caloric and nutrient composition. Because of the dissociation between the timing of EGG changes and the known emptying kinetics, EGG changes seem to reflect other gastric functions rather than being associated with gastric emptying.     

Effect of nifedipine on electrical activity of the brain in rat

The anxiolytic effect of the calcium channel blockers nifedipine and verapamil was tested in mice using two test: the conditioned suppression of the motility test and the black and white box test. The nifedipine but not the verapamil, in low doses (0.1 mg/kg b.w), proved anxiolytic effect and both nifedipine and verapamil in high dose (1.6-2.5 mg/kg b.w) had anxiogenic properties. The anxiogenic effect was correlated with the capacity of the drugs to block the calcium channels and the anxiolytic effect of low doses of the nifedipine was considered to be produced by opening these structures. These data were considered important for a new future aboard of the treatment and pathophysiology of the anxiety.     

Background autonomic activity and "Analytic Perception."

The GSR spontaneity of 22 college students was measured while they were at rest and the number of bursts was found to correlate .61 (     

Origin of tonic electrical activity patterns in the diaphragm of the fetal lamb

The respiratory pattern generator in fetal and postnatal life activates the phrenic nucleus and diaphragm muscle with phasic bursts of activity. In the fetus, diaphragmatic activity is also characterized by tonic activity patterns of unknown origin. We have examined whether such activity is diaphragmatic, or radiated from nearby ribcage muscles, by placing two sets of electrodes side-by-side in the costal portion of the diaphragm in five fetuses. The rationale for this approach is that if tonic activity, radiates to the diaphragm it should be recorded by both sets of electrodes and there should be no delay between the action potentials from each set of electrodes. Of 24 single tonic units identified, 15 were recorded from only one of the two sets of electrodes in the diaphragm. In the 9 tonic units recorded from both sets of electrodes, there was a time delay between the appearance of the action potentials in the two recordings (mean +/- S.E.M. 1.6 +/- 0.2 ms). This is the expected conduction delay along the muscle fibres separating the two electrodes. Since tonic diaphragmatic activity persisted in fetuses with the spinal cord transected rostral or caudal to the phrenic nucleus, we conclude that the spinal cord alone is sufficient to produce the tonic activity recorded from the fetal diaphragm but that the brain may also generate such activity.     

Effects of pemoline on spontaneous and event-related electrical activity of the brain

The effect of pemoline on the electrical activity of the brain (electroencephalogram, EEG) was studied in relation to time since sleep and time of day in 6 healthy subjects carrying out periods of work lasting 18 h. Power of the spontaneous EEG increased with time since sleep and amplitude of the P3 event-related response decreased. The changes may be interpreted as the reduction in alertness with time awake. In contrast, pemoline decreased power of the spontaneous EEG and increased the amplitude the P3 response, effects that are consistent with improved alertness. The changes in brain activity were paralleled by effects on performance, in terms of percentage of correct responses and reaction time. Performance decreased with time awake, and was improved by pemoline compared with placebo. The drug counteracted the adverse effects of time since sleep, with the beneficial effect of the drug persisting over the 18-hour period of work. The findings emphasise that spontaneous and event-related activity of the EEG may be used both to complement measures of performance in the laboratory and to assess behaviour in occupational situations where performance testing is impractical.     

Effects of muscle electrical activity on the transmission of developing neuromuscular junction

A prospective cohort study in a neonatal intensive care unit (ICU) was carried out to evaluate whether the incidence of infection in neonates receiving intestinal decolonization was reduced in comparison to those who did not. This study was performed after controling possible confounding infection risk factors. A total of 536 babies were screened in our ICU during the 27-month study period. Neonates were admitted to the ICU for different reasons: low weight, respiratory distress syndrome, acute fetal suffering, surgery, etc. The doctor in charge decided whether the baby should be decolonized or not, so this experimental study was non-random. Thus more of the babies with a greater risk of infection were decolonized more often than the other babies who were not so much at risk. In this study, babies were classified by type of decolonization given: a well-performed Selective Intestinal Decolonization (SID) was done (early and with three oral drugs: E polymyxin, tobramycin and nystatin): 10.8% of the babies; Incorrect SID (was begun late and/or less than three drugs were used): 16.7% of the babies; and Without SID (72.9%). Total nosocomial infection (NI) was 11.2%, catheter-associated sepsis was 42% of the total NI. When the NI incidence was directly compared among groups, it was lower in the group without SID, but infants with decolonization initially had more infection risk factor than the first group. For this reason, multiple logistic regression was used in order to stratify factors by infection probability, and correcting the existing bias.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of muscle electrical activity during indirect rhythmic stimulation

A mathematical model of transformation of the electrical signals in the peripheral neuromuscular junction, and a method of analysing the experimental data obtained in experiments on the muscle and muscle fibers of rat diaphragm in indirect rhythmic stimulation is described. The parameters characterizing the muscle by frequency potentiation and depression properties were determined as a result of the EMG analysis.     

Effects of nicotine on neocortical electrical activity in rats

The present study investigates the effects of acute and repeated nicotine i.p. treatment on cortical EEG activity. Nicotine at 0.3 and 0.9 mg/kg, but not at 0.1 mg/kg, decreased high voltage spindles (HVSs). Nicotine at 2.7 mg/kg suppressed HVSs completely. Mecamylamine, a nicotinic cholinergic antagonist, increased HVSs at 5 and 7.5 mg/kg. Nicotine blocked the HVS induction induced by mecamylamine. Mecamylamine at 1.25 mg/kg antagonized the HVS suppressing action of nicotine at 0.3 mg/kg. The muscarinic cholinergic antagonist, scopolamine (0.2 mg/kg), increased the 1 to 20 Hz amplitude sum value, and this increase was blocked to some extent by the highest dose of nicotine (2.7 mg/kg). However, nicotine did not block the effect of a higher scopolamine (2.0 mg/kg) dose on the sum amplitude values. Mecamylamine at 2.5 and 7.5 mg/kg blocked the effect of nicotine at 2.7 mg/kg on the EEG sum amplitude values in scopolamine (0.2 mg/kg)-treated rats. The peripherally acting nicotinic and muscarinic cholinergic antagonists, hexamethonium and scopolamine methylbromide, had no effect on spectral EEG and HVS values. In quisqualic acid nucleus basalis-lesioned rats, a frontal cortical choline acetyltransferase depletion (-72%) and slowing of the EEG was observed. Nicotine could not restore EEG activity in nucleus basalis-lesioned rats. After repeated (10 days, three injections/day) administration of nicotine, no tolerance to the effects of either nicotine (0.9 mg/kg) on spontaneously occurring HVSs or nicotine (2.7 mg/kg) on the EEG change induced by scopolamine was observed. The present results show that nicotinic receptor stimulation desynchronizes neocortical EEG activity in normal animals, but this action disappears in basal forebrain-lesioned animals. Therefore, it is likely that the effects of nicotine in reversing EEG and behavioral abnormalities observed in Alzheimer's disease may be limited if the basal forebrain cell loss is extensive.     

Noradrenaline modulates the electrical activity of white adipocytes by a cAMP-dependent mechanism

The two-compartment open model is currently used to assess the glomerular filtration rate (GFR) after a single intravenous injection or a constant rate intravenous infusion. This model needs multiple blood samples from a patient, thus numerous limited sampling models have been so far developed to reduce the number of blood samples. In the present study, the three-, four- and n-compartment closed models have been developed to assess GFR after and during a constant rate intravenous infusion, which include the renal and all possible non-renal elimination pathways. Although more non-renal elimination compartments were included in the modelling, the results show it only leads to the increase in the similar analytical solutions for these compartments and the analytical solution for the blood compartment is the same as that in the two-compartment open model. Theoretically, the developed models can be used to assess GFR with a single blood sample at any sampling time with several urine samples.     

Control of spine formation by electrical activity in the adult rat cerebellum

Dendritic spines are a key structure in neuronal plasticity. Enhanced activity is commonly associated with an increase in spine size and density. Purkinje cell dendrites are characterized by a proximal and a distal compartment on which climbing fibers and parallel fibers, respectively, impinge. The proximal region has a very low spine density, whereas the distal region has a high density. Previous experiments showed that after climbing fiber deletion, Purkinje cells become hyperactive, and a large number of spines develop on the proximal dendrites. Here we show that the same hyperspiny transformation occurs in the proximal dendrites of adult Purkinje cells by depressing electrical activity with tetrodotoxin. Thus, spines in different dendritic compartments are created or maintained independently from the level of Purkinje cell-firing rate and when the afferent activity is blocked. This conclusion supports the view that spinogenesis is the expression of an intrinsic program and the two regions of the dendritic tree respond differently to activity block because of differences in the inputs that they receive. On tetrodotoxin treatment, climbing fibers become atrophic and may sprout thin collateral ramifications directed mainly toward the granular layer. All changes are reversible on tetrodotoxin removal. Therefore, Purkinje cells provide a model where spines in different compartments of the same neuron are differently regulated by the activity of their local afferents. In addition, electrical activity is also essential to maintain the full climbing fiber innervation.