Effects of chronic left vagal stimulation on visceral vagal function in man

We examined the effects of chronic left vagal electrostimulation on afferent and efferent gastrointestinal vagal function in eight patients. Afferent function was assessed using cortical evoked responses to electrical stimulation of the esophagus and to direct vagal stimulation using the implanted left vagal electrode. Efferent gastrointestinal vagal function was measured by examining the basal, maximal, and sham fed stimulated gastric acid output prior to and with chronic left vagal electrostimulation. Esophageal electrostimulation produced a cortical evoked response consisting of three negative and three positive peaks within 400 msec after stimulation. Prior to vagal electrostimulation the mean conduction velocity of the afferent signal was measured at 8.72 +/- 3.39 m/sec, compatible with A-delta fibers involvement. Basal, maximal, and sham fed acid output were 1.11, 21.87, and 9.37 mmol/hour, respectively. The evoked response to esophageal electrical stimulation was not changed with chronic left vagal electrostimulation. Direct vagal stimulation also produced evoked potentials that were comparable to those obtained with esophageal stimulation. The mean conduction velocity was 6.26 +/- 2.72 m/sec (NS) so that there was no evidence of loss of myelinated fibers with chronic stimulation. No differences were detected in basal (1.29 mmol/h), maximal (21.64 mmol/h), or sham fed stimulated (8.03 mmol/h) acid output, showing that vagal electrostimulation has no effect on either total or vagally mediated acid output, an efferent vagal function. In conclusion, chronic left vagal electrostimulation has no significant adverse effect on gastrointestinal vagal function.

Translocation of particulates across the gut wall--a quantitative approach

The translocation of latex particles across the epithelium of the rat small intestine and their transfer to internal organs was determined and quantified. The rate of particle uptake was also established. Particle uptake from the gut lumen to internal tissues was rapid as they were detected in all tissues examined within 30 minutes of oral administration. The maximum number of particles per gram tissue was detected in tissues of the small intestine. Particle number in spleen, kidney, lung, liver and brain increased with time, and in mesenteric lymph node, and heart tissues they decreased with time. Particles were also detected in bone marrow samples. These findings suggest that this animal model is useful in the evaluation and quantification of particle uptake and the determination of the tissues to where they are transported.

The cerebral response to electrical stimuli in the oesophagus is altered by increasing stimulus frequencies

Recording of cerebral evoked responses (EP) allows the assessment of visceral afferent pathways and gut-brain communication, but the optimal stimulation parameters remain to be established. The present study determined the optimal stimulation frequency of electrical stimulation of the oesophagus to elicit EP responses. In 13 healthy male volunteers (24.1 +/- 5.9 years), a 5 mm stainless-steel electrode was placed in the distal oesophagus for electrical stimulation (ES). EP were recorded from 21 scalp electrodes placed according to the 10/20 International system. ES (15 mA, 200 microseconds) were delivered in repeated series of 24 stimuli. Stimulus frequency was randomly altered in different series using a pseudologarithmic range (0.1, 0.2, 0.3, 0.5, and 1 Hz). Two series of stimuli were applied using each stimulation frequency. Two-dimensional topographic brain maps were created using interpolation techniques at each stimulation frequency. With increasing stimulus frequency, a significant and progressive decrease of EP amplitudes was observed between frequencies of 0.1 Hz and 1.0 Hz (P1/N2: 7.6 +/- 1.2 vs 1.4 +/- 0.3* microV, N2/P2: 17.2 +/- 1.7 vs 4.6 +/- 0.4* microV, P2/N3: 6.9 +/- 0.7 vs 4.2 +/- 0.5* microV; * = P < 0.05). In addition, there was a significant shortening of the mean peak latency of the intercalated P2 peak (P < 0.0005), with a similar trend for the P3 peak (P < 0.06), with increasing stimulus frequency from 0.1-1.0 Hz. Topographic brain maps localized the maximal early peaks (N1,P1.N2) in the paracentral cortical region (C3, Cz, C4), whereas the later peaks (P2 to P3) were symmetrically spread over the centroparietal and temporal regions (Cz, Pz, T5, T4). There was no difference in the cortical location of maximal EP amplitudes with increasing stimulus frequency. In conclusion, there is a clear relationship between stimulus frequency and amplitude of EP, suggesting rapid attenuation of the cerebral autonomic neural responses with increased electrical stimulation frequency. The effect of increased frequency on peak latencies suggests an alteration of stimulus processing in the thalamocortical region due to an altered perception of stimuli. Early EP peaks originate from basal structures of primarily the dominant hemisphere, while later peaks are localized in centroparietal cortical regions.

Cognitive evoked potentials to anticipated oesophageal stimulus in humans: quantitative assessment of the cognitive aspects of visceral perception

Evoked potential studies provide an objective measure of the neural pathways involved with perception. The effects of cognitive factors, such as anticipation or awareness, on evoked potentials are not known. The aim was to compare the evoked potential response to oesophageal stimulation with the cortical activity associated with anticipation of the same stimulus. In 12 healthy men (23.5 +/- 4 years), oesophageal electrical stimulation (15 mA, 0.2 Hz, 0.2 msec) was applied, and the evoked potentials recorded using scalp electrodes. A computerized model of randomly skipped stimuli (4:1 ratio) was used to separately record the evoked potentials associated with stimulation and those associated with an anticipated stimulus. The electrical stimulus represented the nontarget stimulus and the skipped impulse the target (anticipatory) stimulus. This anticipatory evoked potential was also compared to auditory P300 evoked potentials. Reproducible evoked potentials and auditory P300 responses were elicited in all subjects. Anticipatory evoked potentials (peak latency 282.1 +/- 7.9 msec, amplitude 8.2 +/- 0.7 microV, P < 0.05 vs auditory P300 evoked potential) were obtained with the skipped stimulus. This anticipatory evoked potential was located frontocentrally, while the auditory P300 potential was located in the centro-parietal cortex. The anticipatory evoked potential associated with expectation of an oesophageal stimulus, although of similar latency to that of the auditory P300 evoked response, originates from a different cortical location. The recording of cognitive evoked potentials to an expected oesophageal stimulus depends on attention to, and awareness of, the actual stimulus. Anticipatory evoked potentials to GI stimuli may provide an objective electrophysiological tool for the assessment of the cognitive factors associated with visceral perception.

Effects of esophageal stimulation in patients with functional disorders of the gastrointestinal tract

We studied the effects of esophageal electrical stimulation on cortical-evoked potentials (EPs) and power spectrum of heart rate variability (PS/HRV) in patients with diabetes and non-cardiac chest pain (NCCP). We also recorded cognitive-evoked potentials (P300 EPs) in response to an odd-ball stimulation in patients with NCCP. Diabetic patients did not yield reproducible cortical EPs. Their power spectra of heart rate variability (PS/HRV) showed an increased vagal modulation during stimulation. In patients with NCCP the P300 EPs were of greater amplitude (17 +/- 3 microV vs. 12 +/- 1 microV in controls, p < 0.04), while peak latencies were slightly elongated in patients (382 +/- 22 ms vs. 354 +/- 12 ms in controls). The PS/HRV in these patients also showed an increased vagal modulation of the sinus node activity. Our results suggest the following: (1) in patients with diabetes, afferent pathways and processing of sensory signals are likely to be impaired; (2) an increased perception of esophageal stimulation reflects an exaggerated brainstem response and altered cortical processing of visceral sensation in patients with NCCP.

Estimation of habituation and signal-to-noise ratio of cortical evoked potentials to oesophageal electrical and mechanical stimulation

Electrical and mechanical stimulation of the oesophagus has been recently proposed to examine the physiological effects of autonomic stimulation in humans. Cortical evoked potentials (EPs) to oesophageal stimulation provide an assessment of afferent fibres and central processing. However, habituation takes place during averaging of cortical EPs and reduces the signal-to-noise ratio (SNR) as the number of stimuli increases. The SNR of cortical EPs to oesophageal stimulation is computed for 15 normal subjects. Habituation is characterised by the Euclidean distance between the EEG response to single stimuli and the averaged EP, to serve as an objective measure of similarity between the averaged EP and the single-stimulus EEG. With electrical stimulation, the SNR is highest (0.41 +/- 0.21) for 1-12 stimuli and then significantly decreases to 0.2 +/- 0.08 for 13-24 stimuli (p < 0.001). With balloon distension (BD), the SNR is highest (0.22 +/- 0.16) for 1-12 stimuli and lowest (0.12 +/- 0.14) for 13-24 stimuli, but these SNRs are not significantly different from each other. Both electrical and mechanical stimulation of the oesophagus produce rapidly adapting EPs. The SNR of the EPs is higher with electrical stimulation than with BD. The EPs response to BD has a higher variability and is more noisy. Consequently, these results suggest that the overall cortical EP response to electrical stimulation of the oesophagus is more reproducible than that due to balloon distension.

Objective assessment of cognitive factors involved in visceral perception by using event-related cerebral evoked responses to esophageal target stimulation in man

Evoked potential (EP) studies provide an objective measure of the neural pathways involved with perception of gastrointestinal stimulation. The effects of cognitive factors, such as anticipation or awareness, on EP responses are not known. We compared the EP response to esophageal electrical stimulation with the cortical activity associated with target detection and anticipation of the same stimulus. In 12 healthy men (26.8+/-6 years old), esophageal electrical stimulation (0.2 Hz, 0.2 msec, 15 mA) was applied, and the EP recorded using scalp electrodes. A computerized model of randomly applied target stimuli (1:5 ratio) was used to separately record the EP associated with stimulation and the event-related cognitive EP associated with a dual task-related or anticipated stimulation approach. A periodic electrical stimulus represented the nontarget stimulus and a second electrical impulse (oddball model) or an omitted stimulus (anticipatory model) the target stimulus. The event-related cognitive EP responses were also compared with standard and anticipatory auditory P300 evoked potentials. The esophageal and auditory oddball stimulus approach elicited event-related P300EP in all subjects. P300EP associated with electrical stimulation had a longer peak latency (P < 0.0001) and smaller amplitude than those obtained with auditory stimulation. Anticipatory evoked potentials could be obtained by electrical skipped stimulation in 8 of 12 subjects. These EP were similar to those obtained with omitted auditory target stimulation, although of significantly smaller amplitude than auditory standard P300EP (P < 0.001). In conclusion, the brain response associated with directed effortful processing of discriminate esophageal stimuli consists of a large event-related potential (P300EP). Anticipatory stimulation produces a similar event-related cortical response, which is associated with attention to and awareness of the actual stimulus. The P300EP to gastrointestinal stimuli may provide an objective and powerful electrophysiological tool for the assessment of the cognitive factors associated with visceral perception.

Effect of animal age on the uptake of large particulates across the epithelium of the rat small intestine

A quantitative investigation into the transfer of latex polystyrene particles across the epithelium of the small intestine has been carried out using male weanling, adult and aged Sprague-Dawley rats. Orally administered polystyrene particles, 2 microns in diameter, were transferred from the lumen of the small intestine into the gut associated lymphoid tissues (Peyer's patches). No significant difference in the number of particles transported across the gut epithelium was detected between animals of different age groups. The concentration of particles detected in Peyer's patches excised from the proximal and distal regions of the small intestine of particle-treated animals did not differ significantly, except in aged rats. Particle concentration was significantly higher in Peyer's patch tissue than in adjacent Peyer's patch-free tissues of the small intestine in treated animals of all age groups. The assay method described here may be used for quantitative investigation of the transepithelial transport of large particulates.

Effects of esophageal stimulation in healthy subjects

We studied the effects of esophageal electrical stimulation on heart rate variability power spectra (PS/HRV) and cortical evoked potentials (EPs) in healthy subjects. The intensity of stimulation was varied from 2.7 to 20 mA. We found that the amplitude of the cortical evoked potentials (amplitude of the N2/P2 peak) increased from 5.1 +/- 0.7 microV at 5 mA to 16.3 +/- 1.1 microV at 20 mA. The PS/HRV showed an increase in the vagal modulation of the sinus node. When the stimulation frequency was varied from 0.1 to 1 Hz at a constant intensity of 15 mA, the amplitude of cortical EPs (N2/P2 peak) decreased with increase in the frequency of stimulation (p < 0.05). The LF:HF ratio decreased significantly for all frequencies of stimulation (p < 0.005). An experimental paradigm to evoke the cognitive component in the cortical EPs yielded a peak around 354 ms following the stimulus.

Synthesis of Salmonella enteritidis Antigenic Tetrasaccharide Repeating Unit by Employing Cationic Gold(I)-Catalyzed Glycosylation Involving Glycosyl N-1,1-Dimethylpropargyl Carbamate Donors

Synthesis of an antigenic tetrasaccharide repeating unit of the O-polysaccharide of Salmonella enteritidis lipopolysaccharide has been accomplished. Those four monosaccharides were assembled stereoselectively by employing our recently developed cationic gold(I)-catalyzed glycosylation methodology involving various glycosyl N-1,1-dimethylpropargyl carbamate donors. The newly formed α-anomeric stereochemical configuration was controlled by the axial C2-OBz of the glycosyl donors via anchimeric assistance.

Assessment of the visceral afferent and autonomic pathways in response to esophageal stimulation in control subjects and in patients with diabetes

OBJECTIVE

To examine the effects of esophageal stimulation on vagal afferent and efferent pathways in volunteers without diabetes and patients with diabetes.

DESIGN

Prospective physiological study.

PARTICIPANTS

Fourteen control subjects without diabetes and 6 patients with diabetes.

INTERVENTIONS

Electrical and mechanical stimulation of the esophagus.

OUTCOME MEASURES

Cortical evoked potentials and the power spectra of heart rate variability.

RESULTS

For the control subjects, there was a significant decrease in the ratio of the low frequency to high frequency (LF:HF) power (i.e., increased vagal efferent modulation) during stimulation. Reproducible cortical evoked potentials were obtained from all control subjects. In the 6 patients with diabetes, who had viscerosensory and autonomic neuropathy, the cortical evoked potentials showed an erratic non-reproducible response to electrical esophageal stimulation; however, the LF:HF ratio decreased in these patients during stimulation, suggesting an intact subcortical reflex circuit.

CONCLUSIONS

Vago-afferent fibres can be studied using minimally invasive techniques, and the power spectral analysis of heart rate variability permits study of autonomic vago-efferent pathways.