Reproducibility of antroduodenal motility during prolonged ambulatory recording

Ambulatory recording of antroduodenal manometry is a novel technique with several advantages over standard stationary manometry recording. Although the feasibility of this technique in clinical practice has been demonstrated, reproducibility of antroduodenal motility recorded by means of ambulatory manometry has not been investigated. To test whether antroduodenal motility recorded by ambulatory manometry is reproducible, we performed two 24-h ambulatory antroduodenal manometry recordings in 18 healthy subjects according to an identical protocol with a 1-week interval. Motility was recorded with a five-channel solid-state catheter. Postprandial motility was recorded after consumption of two test meals and interdigestive motility was recorded nocturnally. Postprandial antroduodenal motor characteristics were identical between the separate recordings. The number and duration of nocturnal cycles of the interdigestive migrating motor complex were also in the same range. Phase III characteristics in general were not different between the two recordings. Only minor alterations were observed in the duration of phase III motor fronts with duodenal onset and in the number of interdigestive cycles concluded by duodenal onset phase III. Parameters obtained by qualitative analysis were comparable between the two recordings. The antroduodenal motility pattern, when measured by ambulatory recording with solid state catheters under standardized conditions, is very reproducible.     

Phase III of the migrating motor complex: associated with endogenous xenin plasma peaks and induced by exogenous xenin

Xenin, a recently discovered peptide produced by specific endocrine cells of the duodenal mucosa, has shown exocrine, endocrine and motility effects in the gastroenteropancreatic system in animal experiments. The aim of the present investigation was to study the role of xenin in the regulation of duodenojejunal motility of humans. Twenty-nine healthy volunteers from the hospital staff gave informed consent to participate in this investigation. In 20 volunteers, we determined plasma concentrations of immunoreactive xenin at 15 min intervals over a mean time period of 8 h fasting and recorded the interdigestive motor activity of the duodenojejunum. In a double-blind randomized crossover study on other nine subjects, synthetic xenin in a dose of 4 pmol kg-1 min-1 or placebo was infused for 10 min intravenously in the interdigestive period and postprandially after a liquid meal. Duodenojejunal motility was recorded simultaneously. Predefined interdigestive xenin plasma peaks were found to be significantly associated with the phases III of the migrating motor complex. In the interdigestive period, xenin induced a premature phase III activity in each volunteer; this was followed by a second phase III in five out of nine subjects. In the postprandial state, xenin significantly increased contraction frequency and the percentage of aborally propagated contractions. These findings suggest a role of the peptide hormone xenin in modulating interdigestive and postprandial duodenojejunal motility in humans.     

Effects of duodenal flow on interdigestive patterns of small bowel myoelectric activity

Factors regulating the conversion of the interdigestive migrating motor complex (MMC) to postprandial patterns of motility are not completely understood. This study assessed the effects of varying rates of nonnutrient duodenal flow on patterns of interdigestive motility before and after abdominal vagotomy. Six neurally intact dogs were prepared with serosal intestinal electrodes and a duodenal infusion catheter. After recovery, the dogs were studied by infusing an isosmolar, noncaloric, balanced electrolyte solution at rates of 0, 3, 6, 9, or 12 ml/min for 5 hours into the proximal duodenum. With increasing rates of duodenal infusion, the duration of phase I decreased progressively (P < 0.05), while the period of the MMC remained unchanged. The MMC was eventually inhibited at rates of 9 or 12 ml/min with establishment of a pattern of intermittent spike activity. These findings were similar in 3 of these dogs after transthoracic total abdominal vagotomy. Our findings suggest that increases in duodenal infusion rate, independent of caloric or nutrient content, modulate patterns of intestinal motility during the postprandial period; this effect does not appear to be vagally mediated.     

Gastric myoelectrical and antroduodenal motor activity in patients with achalasia

Achalasia is a primary motor disorder of the oesophagus, in which the myenteric plexus is involved. However, abnormalities in other parts of the digestive tract have also been described in achalasia. Whether gastric myoelectrical and duodenal motor activity in these patients is also affected is unknown. Therefore, interdigestive and postprandial gastric myoelectrical and antroduodenal motor activity were studied in 11 patients with achalasia, using electrogastrography (EGG) and stationary antroduodenal manometry.
Electrogastrographically, no differences were found in the gastric frequency, incidence of dysrhythmias and postprandial/fasting power ratio. In the interdigestive state a lower propagation velocity of phase III episodes was found in the achalasia patients, but other parameters were unaltered. Postprandially, no differences were found in the number of pressure waves, in the amplitude of pressure waves or in antro-duodenal coordination.
We conclude that gastric myoelectrical activity and antral motor activity in patients with achalasia is normal, suggesting an intact extrinsic and intrinsic neural innervation of the distal stomach. Although postprandial duodenal motility is normal, a lower propagation velocity of phase III suggests involvement of the small intestine in achalasia.     

Twenty-four hour ambulatory antroduodenal manometry in normal subjects (co-operative study)

Circadian antroduodenal motor activity was studied in 40 normal subjects by means of a portable recording system consisting of a computerized data logger and a probe with microtransducers. The quantitative and qualitative characteristics of contraction events during the interdigestive and digestive periods, as well as during the awake and asleep periods, were analysed. The composition and timing of meals and night recumbence were standardized. In spite of the high interindividual variability in motor parameters, significant differences in the characteristics of interdigestive and digestive periods between waking and sleep states were found. This paper confirms the existence of a circadian variation in antroduodenal motor activity and provides reference values from a large series of normal subjects that can be used for statistical comparisons with those obtained from patients recorded with the same method.     

Postprandial peristalsis in the human duodenum

MMC-related retroperistalsis is a cyclical phenomenon in the duodenum linked to phase III. The aim of this study was to elucidate the direction of propagation of juxtapyloric duodenal pressure waves in the postprandial state in healthy humans and to compare with the contractions in the interdigestive phase II. Antroduodenal manometry was performed in 11 healthy subjects. Individual pressure waves propagating along a 6-cm duodenal segment were analysed with respect to the proportions of antegrade and retrograde propagation in the four duodenal subsegments (D1–D2) to (D4–D5), each subsegment being 15 mm. A test meal was given 30 min after a phase III had passed and motility recording continued for 60 min after the meal. During both the first and the second 30-min period of postprandial recording the proportion of retrograde pressure waves was larger just distal to the pylorus, (D1–D2), 40% (23–68) and 50% (23–68), respectively, compared to the distal part, (D4–D5), of the duodenal segment, 29% (12–30) and 10%(10–24), respectively (P < 0.05 and 0.01). In contrast, during late phase II of the interdigestive state antegrade pressure waves predominated in all four duodenal subsegments. We conclude that in the postprandial state a high proportion of the duodenal pressure waves (40–50%) is retrograde in the immediate juxtapyloric area while antegrade contractions predominate at a distance 5–6 cm distal to the pylorus. These manometric data together with recent observations of postprandial transpyloric liquid flow, indicate that retrograde duodenogastric propelling of contents may be an important determinant for the gastric emptying rate.     

Manometric artefacts suggesting compression of the duodenum by the superior mesenteric artery in healthy humans

Multi-channel manometry offers the opportunity to study intestinal motor activity with high spatiotemporal resolution. We report tonic and phasic intraluminal pressure changes in the mid-portion of the horizontal part of the duodenum. In 10 healthy volunteers, we recorded 2 h of interdigestive duodenal motility using a water-perfused catheter. The assembly incorporated 12 duodenal sideholes at 1.5-cm intervals (D1-D12). Measurement of the antral and duodenal transmucosal potential difference (TMPD) was used to maintain a correct position of the catheter. The incidence of pressure waves (PWs) increased gradually from proximal (D1) to distal (D12) (P < 0.0001), while the mean amplitude of PWs decreased (P < 0.0001). In eight of 10 subjects, the signals recorded from D9 showed tonic pressure elevations with superimposed phasic pressure changes at heart-rate frequency, comprising 13.8% of total recording time. In the other two subjects, this phenomenon occurred in D8 (9.9% of time). D10 showed a lower incidence of PWs compared with neighbouring sideholes (D6-D9/D11-D12) (P < 0.035), with normal amplitudes. Fluoroscopy was performed in three subjects and showed that D9 was located at the midline. In healthy subjects manometric signals recorded from the horizontal part of the duodenum showed localized artefacts, presumably caused by compression by the superior mesenteric artery. In addition, a 'silent' region was present just distal to this site, the origin of which is uncertain.     

Altered periodic rectal motor activity: a mechanism for slow transit constipation

The pathophysiology of slow transit constipation is poorly understood. Both decreased and increased distal colonic motility have been reported. In healthy humans, a 3 cycles per minute (cpm), periodic rectal motor activity (PRMA) has been described. Our aim was to investigate the characteristics of PRMA and to assess its role in the pathogenesis of constipation. A six-sensor solid-state probe was placed with the tip sensor in the mid-transverse colon, without sedation, and prolonged colonic motility was recorded in nine patients with slow transit constipation (1M, 8F) and in 11 healthy subjects (3M, 8F). Subjects were free to ambulate. We examined the frequency, nocturnal vs. diurnal variation, and characteristics of PRMA, and its relationship to proximal colonic motility. All subjects showed PRMA. The rhythm was similar (2.5-4 cpm) in both groups. However, constipated patients exhibited a greater (P < 0.001) number of PRMA cycles than controls. The duration of each cycle and amplitude of pressure waves during PRMA were also greater (P < 0.05) at night in patients compared with controls. In patients, 40% of PRMA cycles were associated with a proximal colonic motor event compared with 81% in controls (P < 0.02). The area under the curve of all colonic pressure waves and incidence of specialized propagating pressure waves was lower (P < 0.05) in patients during daytime. When compared with controls, constipated patients exhibited reduced daytime colonic pressure waves and a higher frequency of PRMA. Most of the PRMA was unrelated to proximal colonic activity in constipated patients in contrast with findings in control patients. In addition to decreased colonic motility, this excessive and unco-ordinated phasic rectal activity may further impede stool transport and contribute to the pathogenesis of slow transit constipation.     

Inhibition of the migrating motor complex by duodenal drainage in man

Abstract The effect of varying bile acid output on fasting small intestinal motility was investigated in healthy male volunteers. Biliary output was manipulated by jejunal infusion of isotonic mannitol, which resulted in increased output, and by prolonged drainage of duodenal contents, which resulted in decreased output. Intestinal motility was measured by manometric recordings performed at four levels in the proximal small intestine. A marker dilution technique was used to measure pancreatico-biliary output. There were three experimental groups: duodenal drainage, non-drainage and control. Both duodenal drainage and non-drainage groups underwent jejunal saline infusion, followed by mannitol infusion. The control group did not receive drainage or infusions. In the drainage group, 0.41 (0.13-0.68) activity fronts of the migrating motor complex (MMC) per hour were recorded during saline infusion, but only 0.06 (0-0.19) activity fronts per hour were observed during mannitol infusion. In the nondrainage group, 0.71 (0.61-0.81) activity fronts per hour were observed during saline infusion and 0.50 (0.18-0.82) activity fronts per hour were recorded during mannitol infusion. In the control group, 0.58 (0.33–0.84) activity fronts per hour were recorded during the first 4-h session and 0.58 (0.45-0.71) activity fronts per hour during the second session. There was no difference between the number of activity fronts per hour observed in the control group and those observed in the saline infusion of the drainage group. In contrast, there was a significant decrease in the number of activity fronts per hour in the drainage group during mannitol infusion, compared to both non-drainage group during mannitol infusion (P < 0.01) and controls (P < 0.05). In conclusion, decreased biliary output caused by duodenal drainage in combination with mannitol infusion is associated with inhibition of the cyclic activity of MMC in the proximal small intestine in man.     

Fully automated analysis of colonic manometry recordings

The purpose of this study was to develop a computer program for fully automated analysis of all presently known motor patterns in human colonic motility recordings. Colonic pressure recordings obtained from 24 healthy volunteers were used. Algorithms were developed for the detection and numerical analysis of five types of pressure waves: antegrade, retrograde, simultaneous, high-amplitude and isolated pressure waves. Furthermore, periodical motor activity was quantified. Validation was performed by comparison with visual analysis by two experienced observers. Patterns recorded during day- and night-time were compared using multiple-factor analysis of variance with Bonferroni correction. Automated analysis correlated well with visual peak detection (r = 0.98, P <0.01) and detection of antegrade pressure waves (r = 0.98, P <0.01). Most motor patterns showed a diurnal variation. During the night, prevalences of antegrade (938 vs 455; P <0.05), retrograde (112 vs 81; P <0.05), high-amplitude (12.9 vs 1.3; P <0.05), isolated pressure waves (1114 vs 765; P <0.05), and periodic motor activity were decreased (7.33 vs 4.47%; P <0.05). However, when expressed as percentage of absolute numbers of pressure waves, prevalences remained constant. In conclusion, fully automated analysis of all hitherto described colonic motility patterns is feasible. During the night, overall wave prevalences markedly decreased, but the distribution over the various motor patterns was preserved.     

Coordination of biliary and upper gastrointestinal motility in the fasted conscious pig

Abstract A chronic pig model was developed which permits the simultaneous measurement of integrated biliary motility as resistance to flow (CBD inflow), gallbladder, duodenal and gastric motility in addition to collection of venous blood samples for gut hormones estimations. Animals displayed a duodenal interdigestive cycle of 55.4 ± 3.4 min (mean ± SEM, n = 6), consisting of phase I, II and III (21.2 ± 2.1, 70.5 ± 2.0, 8.7 ± 0.5% of the cycle, respectively). A gastric inter-digestive cycle of 60.2 ± 6.5 min (n = 4) was similarly demonstrated consisting of three phases which corresponded to the three duodenal phases. The gastric phases I, II and III comprised 26.3 ± 3.0, 71.2 ± 2.7 and 2.5 ± 0.8% of the cycle, respectively. The gastric phase III immediately preceded the onset of the duodenal phase III. The gallbladder likewise displayed an interdigestive cycle of 54.5 ± 7.2 min (n = 6) consisting of a quiescent period (37.2 ± 3.7% of the cycle) corresponding temporally to duodenal phase III and phase I. This quiescent phase was followed by a period of rhythmic contractions (64.5 ± 4.1% of the cycle) which corresponded temporally to duodenal phase II. The onset of the gallbladder quiescent period coincided with the onset of duodenal phase III. The CBD inflow similarly demonstrated an interdigestive cycle of 53.4 ± 9.6 min (n = 4) duration, consisting of three phases. The initial phase was evident as a period of rapid inflow, the onset of which coincided with the onset of duodenal phase III and the gallbladder quies-centperiod, andoccupied 12.0 ± 0.8% of the cycle. The secondphase which occupied 18.0 ± 7.4% of the cycle, was typified as a period of declining inflow which reached a relatively stable level at a time corresponding to the end of duodenal phase I. The third phase consisted of the maintenance of the inflow rate achieved at the end of the previous phase (60% of maximum inflow), corresponding in onset and duration with duodenal phase II and occupied 70.0 ± 8.6% of the cycle. Plasma motilin levels fluctuated in relation to the duodenal interdigestive cycle, peaking during phase III relative to phase I (36.9 ± 8.5 vs 25.4 ± 7.7 pg mL^?1, respectively, n = 5, P < 0.05). Cholecystokinin levels did not fluctuate, remaining low (2.3 ± 2.1 pM cholecystokinin octapeptide equivalents, n = 5) throughout the duodenal interdigestive cycle, but increased about two fold after ingestion of solid food. Feeding disrupted the gastric, duodenal, gallbladder and CBD inflow cycles.     

Activity Fronts of Migrating Myoelectric Complex: Initiation by Luminal Bile Acids in Rat Small Intestine

The aim of the present study was to investigate the possible role of bile in regulation of fasting small intestinal motility in the rat. Myoelectric activity was recorded by bipolar electrodes implanted in the jejunum, 15, 25, and 35 cm distal to the pylorus. After recording migrating myoelectric complexes (MMCs), total biliary drainage was performed by cannulating the bile duct of 15 rats. After biliary drainage for 267 (222–312) minutes (mean and 95% confidence interval), a characteristic continuous irregular spiking activity appeared at all recording sites. When continuous irregular spiking had persisted for 2 hours, a mixture of 20 mM taurocholic and 10 mM taurochenodeoxycholic acid was infused into the duodenum (0.5 μ/mol/min for 90 min) of seven rats. Bile acid infusion induced three to six activity fronts within 25 to 47 minutes in all animals. Maximal bile acid secretion in response to bile acid infusion was obtained about 1 hour after the last induced activity front, when the motility pattern had returned to irregular spiking. In eight rats with biliary drainage but without bile acid infusion, irregular spiking activity persisted for at least 10 hours. In sham-operated rats, regular activity fronts started after 221 (146–296) minutes. Thus drainage of bile changes the motility pattern from MMC to continuous irregular spiking, while duodenal bile acid infusion after biliary drainage reinstates the MMC pattern in rat small intestine.     

Prolonged duodenal acid perfusion and dyspeptic symptom occurrence in healthy volunteers

Abstract  The pathophysiology of functional dyspepsia (FD) is unknown and several mechanisms associated with specific symptom patterns have been recently proposed. Increased duodenal acid exposure has been supposed to be associated with nausea, but recently an increase of severity of several dyspeptic symptoms was noted in a subset of dyspeptic patients. As its pathogenetic role is still unclear, we evaluated an involvement of duodenal acid exposure in symptom generation by inducing a hyperacidity status of the duodenum. Twelve young adult healthy volunteers in a randomized, double-blind protocol, underwent duodenal acid (0.2 N, 5 mL min⁻¹) or saline perfusion, antropyloroduodenal manometry and duodenal pH monitoring both during fasting and postprandially. Every 15 min, severity of discomfort, fullness, bloating, belching, nausea, heartburn, epigastric burning, satiety and pain were evaluated by visual analogue scale. During acid perfusion, symptom scores for discomfort, bloating, nausea, epigastric burning were significantly higher ( P  < 0.01) compared to saline. Postprandial antral motility index was lower (2.96 ± 1.8 vs 3.62 ± 1.8, P  = 0.01) and jejunal motility index higher (4.87 ± 1.0 vs 4.37 ± 1.4, P  = 0.01) during acid perfusion. Occurrence and duration of phases III of the migrating motor complex showed no difference. Duodenal acid perfusion causes a sensitization to dyspeptic symptoms and induces antral hypomotility and jejunal hypercontractility. Through these mechanisms, increased duodenal acid exposure may play a role in the pathophysiology of FD symptoms.     

Gastric emptying and the organization of antro-duodenal pressures in the critically ill.

The motor dysfunctions underlying delayed gastric emptying (GE) in critical illness are poorly defined. Our aim was to characterize the relationship between antro-duodenal (AD) motility and GE in critically ill patients. AD pressures were recorded in 15 mechanically ventilated patients and 10 healthy volunteers for 2 h (i) during fasting, (ii) following an intragastric nutrient bolus with concurrent assessment of GE using the (13)C-octanoate breath test and (iii) during duodenal nutrient infusion. Propagated waves were characterized by length and direction of migration. Critical illness was associated with: (i) slower GE (GEC: 3.47 +/- 0.1 vs 2.99 +/- 0.2; P = 0.046), (ii) fewer antegrade (duodenal: 44%vs 83%, AD: 16%vs 83%; P < 0.001) and more retrograde (duodenal: 46%vs 12%, AD: 38%vs 4%; P < 0.001) waves, (iii) shorter wave propagation (duodenal: 4.7 +/- 0.3 vs 6.0 +/- 0.4 cm; AD: 7.7 +/- 0.6 vs 10.9 +/- 0.9 cm; P = 0.004) and (iv) a close correlation between GE with the percentage of propagated phase 3 waves that were antegrade (r = 0.914, P = 0.03) and retrograde (r = -0.95, P = 0.014). In critical illness, the organization of AD pressure waves is abnormal and associated with slow GE.     

Studies of Small Intestinal Myoelectrical Activity and Intraluminal Pressure Changes in the Unrestrained Conscious Rat

Our aim was to develop and validate a methodology to permit chronic recordings of small intestinal intraluminal pressure changes in the conscious rat and thereby to study regional variations in motor activity. A low-flow (0.014 cc/min) perfusion system permitted reliable intraluminal pressure recordings at four sites along the small intestine from unrestrained animals. Comparison of overall patterns of fasted and fed motor activity and the various parameters of the migrating motor complex (MMC) from these recordings with those obtained from another group of animals prepared with serosal electrodes provided similar results in the proximal small intestine (MMC frequency 3.4 ± 0.5 vs. 3.9 ± 0.3 cycles/h, phase II duration 3.8 ± 0.7 vs. 4.7 ± 0.4 min, and phase III duration 4.0 ± 0.2 vs. 3.5 ± 0.2 min for duodenal catheters vs. electrodes, all NS). However, the distal deal phase II was considerably shorter in catheter than electrode recordings (6.0 ± 0.8 vs. 15.7 ± 2.4 min, p < 0.0001). Both methodologies confirmed significant regional variations in small intestinal motor parameters: the incidence of interdigestive myoelectrical complex (IDMEC) cycles was lower and phase II of the IDMEC was considerably prolonged in the distal Hewn. In summary, a system to permit chronic recordings of small intestinal intraluminal pressure has been developed and validated by comparison to myoelectrical recordings. Motor specialization was evident in the rat distal ileum.     

Postnatal Maturation of Small Intestinal Motility in Preterm and Term Infants

Perfusion manometry was used to study the maturation of small intestinal motility in 15 preterm and term infants before the initiation of enteral feeding (study 1); seven of the 11 preterm infants were restudied after 3 weeks or more of enteral feeding (study 2). During study 1, the interdigestive motility of the four term infants exhibited cycles of quiescence and rhythmic activity, compatible with migrating motor complexes observed regularly in adults; in response to feeding, motility changed to irregular, phasic activity. Preterm infants, however, showed only unorganized clusters of phasic activity during fasting, and there was no consistent pattern of motor response to feeding. After 3 or more weeks of enteral feeding, interdigestive cycles with migratory motor complexes and a consistent, obvious motor response to feeding were present. Preterm infants as young as 32 weeks' gestation showed "mature" motor patterns in study 2, results suggesting that intestinal motility matures with postconceptual age.     

Sleep dysfunction in Rett syndrome: a trial of exogenous melatonin treatment

Nine girls with Rett syndrome (mean age, 10.1 years) were monitored 24 hours a day over a period of 10 weeks using wrist actigraphy. Baseline sleep-wake patterns were assessed for 1 week. Subsequently, patients underwent a 4-week melatonin treatment period in a double-blind, placebo-controlled, crossover protocol that employed a 1-week washout between treatment trials. Melatonin doses ranged from 2.5 to 7.5 mg, based upon individual body weight. Baseline sleep quality was poor compared with healthy children. At baseline the group demonstrated a low sleep efficiency (mean [±SE], 68.0±3.9%), long sleep-onset latency (42.1±12.0 minutes), and a short and fragmented total sleep time (7.5±0.3 hours; 15±2 awakenings per night). Melatonin significantly decreased sleep-onset latency to (mean ± SE) 19.1±5.3 minutes (P<0.05) during the first 3 weeks of treatment. While the variability of individual responsiveness was high, melatonin appeared to improve total sleep time and sleep efficiency in the patients with the worse baseline sleep quality. Finally, a 4-week administration of melatonin appears to be a safe treatment as no adverse side effects were detected, yet long-term effects of chronic melatonin use in pediatric patients are unknown at this time.     

Manometric responses of human duodenum during infusion of HCl,hyperosmolar saline,bile and oleic acid

Abstract Duodenal motor activity is incompletely understood. The purpose of this study was to define the contractile patterns of the duodenum that occur in response to rate controlled injection of various solutions. In nine healthy volunteers we placed a six channel perfused catheter, and recorded pressure activity in the antrum, pylorus and duodenum. Volumes of 10 and 20 mL of 0.9% NaCl, 100 mM HCl (pH 1), 5% NaCl (1711 mOsm/kg), human bile and iso-osmolar sodium oleate were randomly injected into the duodenum at 20 ml/min, starting IS min after phase III migratory motor complex (MMC). A 20 mL bolus of each solution caused more activity (P < 0.05) than a 10 mL bolus, but the motor pattern was similar. The control, 0.9% NaCl, produced occasional pressure waves, whereas bile and sodium oleate induced more (P < 0.05) activity which consisted of low amplitude, isolated or clusters (2–4 cycle/min) of non-propagating pressure waves that occurred at random sites. In three subjects, oleate produced isolated pyloric phasic contractions. In contrast, HCl and 5% NaCl induced high amplitude pressure waves that were seen either at a single channel or at multiple channels, occurring simultaneously. The motility index was also greater (P < 0.05) than that induced by other solutions. Additionally, within 2 min of infusion, a phase III MMC like pattern was observed in five of the nine subjects who received HCl and three of the nine who received 5% NaCl. A non-nutrient iso-osmolar solution induced occasional motor activity. HCl and hyperosmolar solutions induced more frequent and large amplitude, segmental contractions whereas lipid and bile induced fewer and smaller amplitude contractions. The volume, the pH, the osmolar and the nutrient make up of the infusate may each influence the duodenal motor responses.     

Difficulty in estimating localized bowel contraction by colonic manometry: a simultaneous recording of intraluminal pressure and luminal calibre

To examine whether or not intraluminal pressure changes at a site in the human colon reflect with fidelity the local bowel wall contractions or relaxation, endoscopic recording of the changes in colonic calibre as a parameter of the motor events with simultaneous manometry was performed at a fixed site in a prepared sigmoid colon during the interdigestive state. In four of the 12 subjects, a total of 20 phasic pressure waves with an amplitude of 13–22 mmHg and a duration of 13–18 sec were obtained in a 20 min recording session. Eighteen of the 20 phasic pressure waves (90%) were associated not with a decrease (contraction) but with an increase in the calibre (relaxation). The pressure change began 0.2–8.4 sec (mean: 4.5 sec) behind and ended ? 1.8 to 8 sec (mean: 3.5 sec) ahead of the calibre change. In the other eight subjects, no phasic pressure change was recorded in the presence of an overt calibre change. We conclude that manometric phasic pressure change recorded at a site in the empty human colon is not necessarily correlated with the localized contractile activity. Extrapolation of pressure profiles in the colon to motor events at the manometric site should be cautious.     

Factors in the Control of Interdigestive and Postprandial Myoelectric Patterns of Canine Jejunoileum: Role of Extrinsic and Intrinsic Nerves

Our aim was to determine the roles of extrinsic and intrinsic (enteric) neural continuity to the jejunoileum in control of postprandial and fasting motility patterns. Four groups of dogs were prepared: control, neurally intact; intrinsic transection, distal duodenal transection to disrupt intrinsic myoneural continuity with jejunum; extrinsic transection, transection of all extrinsic nerves to jejunoileum; and intrinsic/extrinsic transection, disruption of both intrinsic myoneural and extrinsic neural continuity to jejunoileum. Duodenal and jejunal electrodes were placed to monitor motility. After 2 weeks, the dogs were studied while fasting, after meals, and during intravenous infusions of cholecystokinin octapeptide at 0.5μg/(kg · h) and pentagastrin at 2μg/(kg · h). During fasting, although the migrating motor complex (MMC) occurred in each region, coordination between duodenum and jejunoileum was disrupted in intrinsic/extrinsic transection dogs, but only partially in intrinsic transection dogs. Small meals (50 g of liver) interrupted the duodenal MMC in all groups and the jejunoileal MMC only in control dogs. A larger (500-g) meal disrupted the MMC in both regions for comparable durations in all groups. Cholecystokinin octapeptide and pentagastrin inhibited the MMC in duodenum and jejunoileum in all groups. Both intrinsic myoneural and extrinsic neural continuity play a role in regional coordination of interdigestive and digestive gut motility. Both hormonal and neural factors (central, enteric) participate in the regulation of onset of postprandial motor patterns.