The effect of oleate on pancreatic and bile secretion in the conscious rat

The effects of sodium oleate infused into either the duodenum or the terminal ileum on bile and pancreatic secretion were examined in the conscious rat. Rats were prepared with cannulae draining pure bile and pancreatic juice separately, and with an ileal and two duodenal cannulae. A 40 mM taurocholate solution containing 7 mg/ml bovine trypsin was infused into the duodenum throughout the experiment to replace diverted bile-pancreatic juice to maintain the normal regulation of pancreatic secretion. The intraduodenal infusion of sodium oleate significantly increased pancreatic juice flow, protein, and bicarbonate outputs, whereas it did not affect bile secretion. Intravenous infusion of proglumide (300 mg/kg/hr) did not inhibit pancreatic secretion stimulated by intraduodenal infusion of sodium oleate. An intravenous infusion of atropine (100 micrograms/kg/hr) attenuated protein and fluid secretions but not that of bicarbonate in response to intraduodenal oleate. In contrast, the intraileal infusion of oleate had no effect on pancreatic secretion, whereas it decreased bile flow, bicarbonate, and bile salt outputs. In conclusion, sodium oleate introduced in the duodenum stimulates pancreatic secretion but oleate in the terminal ileum inhibits bile secretion.     

促胰液素和胆囊收缩素族激素对豚鼠肝胆汁分泌的影响

用具备胃瘘和胆瘘的豚鼠于人工维持胆汁酸池恒定的条件下,观察促胰液素(SEC)和胆囊收缩素(CCK)族激素[包括雨蛙肽(CAE)、五肽胃泌素(G5)和内源性CCK]对肝胆汁分泌的影响及其相互作用。结果表明:静脉灌注SEC、CAE或肠内灌注左旋苯丙氨酸(L-PHE,促内源性CCK释放剂)后,胆汁流量、胆汁HCO~-_3和Cl~-排出量均显著增多,并呈剂量-效应关系,但静脉注射G5则无利胆效应。在恒速灌注SEC的背景下,CAE或CCK对胆汁HCO~-_3排出的效应分别大于它们单独给予时的效应(P<0.05或P<0.01)。这些激素对胆汁酸的排出量均无影响。上述结果表明,SEC,CAE和内源性CCK均有利胆作用,所刺激的肝胆汁属于不依赖胆汁酸部分。G5则无利胆效应。对胆汁中HCO~-_3的排出,SEC与CAE或内源性CCK间有相互加强作用。     

Functional activities of the colon of the desert gerbil (Gerbillus cheesmani)

The effects of starvation and undernourishment on the potential differences (pd in mV), basal short-circuit current (Isc in microA/cm(2)), resistance (R in omega) and glucose-dependent short-circuit current (Isc in microA/cm(2)) across stripped sheets of proximal, mid and distal colon of the gerbil (Gerbillus cheesmani) were investigated. The effects of replacing sodium chloride by lithium chloride, replacing chloride in Krebs buffer by gluconate and removing bicarbonate from bathing buffers were also investigated. Starvation (4 days, water ad lib) and undernourishment (50% control food intake for 21 days) had no significant changes on pd and R of the three regions of stripped colon. Starvation increased the basal Isc in the proximal and the mid-colon only while undernourishment increased the basal Isc of three regions of the colon. In addition, starvation and undernourishment increased the glucose-dependent Isc in the three regions. Replacing sodium chloride by lithium chloride caused a slight decrease in the basal Isc of proximal and mid colon taken from starved animals. In undernourished gerbils, although there was a slight decrease in basal Isc of proximal and mid colon the big decrease was observed in Isc of the distal colon. Replacing chloride by gluconate had no effect on the Isc of the different regions of colon taken from fed and starved animals but decreased the Isc of the three regions of undernourished animals. The absence of bicarbonate reduced the Isc of proximal and mid colon taken from starved gerbils and those of three regions taken from undernourished animals. The results of the present study suggest that the Isc of proximal and mid colon from starved gerbils could result from active sodium transport together with bicarbonate secretion while the Isc of the three regions taken from undernourished gerbils results from active sodium absorption together with both chloride and bicarbonate secretion.     

Effects of bile salts on bile formation in rabbits

The effects of different species of bile salts: deoxycholate, taurochenodeoxycholate, ursodeoxycholate, glycodeoxycholate, tauroursodeoxycholate, chenodeoxycholate and cholate (DCA, TCDC, UDCA, GDCA, TUDC, CDCA, CA) on bile secretion were examined in anesthetized rabbits using two different infusion routes. When bile salts were infused intravenously, all bile salts (except for TCDC) significantly increased the volume of bile and bile salt excretion, but their respective efficiency for bile formation was different. The concentration of bicarbonate ion in the bile significantly increased during the choleretic periods induced by DCA, UDCA, GDCA and CDCA but remained unchanged with the other bile salts (CA, TCDC, TUDC). In rabbits, where a bile salt solution was infused in the duodenum and then drained from the intestine through an incision in the distal part of duodenum, none of these bile salts affected bile secretion. The effects of intravenously administered bile salts on rabbit bile secretion are different in terms of their choleretic potency and bicarbonate excretion depending on the species of bile salts used. Furthermore, it was concluded that the intraduodenal infusion of UDCA, which was found to stimulate the pancreatic exocrine function, did not affect bile secretion.     

Is intracellular pH and/or intracellular bicarbonate a determinant of bile salt independent canalicular bile formation? The subject revisited.

Canalicular bile formation is a complex process that involves basolateral and apical cell membrane transport, paracellular transport and vesicular transport, all of which may be subject to regulation by pH. We review the concept that apical cell membrane bicarbonate secretion promotes bile salt independent canalicular bile formation. We show that the presence of paracellular electrolyte transport imposes a severe restriction in interpreting data from ion substitution experiments aimed at demonstrating pH or bicarbonate dependent bile formation. Furthermore, we report on experiments that all show stimulation of bile flow under three disparate experimental conditions: i) intracellular alkalinization in the absence of [HCO3-]i or associated with a decrease of [HCO3-]i, ii) intracellular alkalinization with an increase of [HCO3-]i, and iii) intracellular acidification with increase of [HCO3-]i. It is suggested that both, intracellular pH and intracellular bicarbonate may modulate canalicular bile salt independent bile formation, but it remains conjectural which mechanism is the prevailing one under a given experimental setting.     

The effects of synthetic prostaglandin analogs on canine hepatic bile flow.

The synthetic prostaglandin analogs 16, 16-dimethyl PGF2 alpha and 16, 16-dimethyl PGE2 were administered to dogs with chronic biliary and gastric fistulas. The effects of 16, 16 diMePGF2 alpha and 16, 16 diMePGE2 were evaluated on bile flow and composition and bile adenosine 3', 5' monophosphate (cyclic AMP) secretion. 16, 16 diMePGF2 alpha in doses of 0.125 and 0.25 microgram-kg-min significantly increased hepatic bile flow. The choleresis was characterized by increased chloride and bicarbonate secretion. Measurement by radioimmunoassay of bile cyclic AMP concentration demonstrated no evident increase in bile cyclic AMP secretion associated with the choleresis produced by 16, 16 diMePGF2 alpha. The administration of 16, 16 diMePGE2 in a dose range 0.01 to 1.0 microgram-kg-min did not significantly alter bile flow rates or composition. Bile erythritol-14C clearance, a measure of canalicular bile flow, was significantly increased by PGF2 alpha but not by 16, 16-dimethyl PGF2 alpha, suggesting that the mechanism of action of PGF2 alpha in stimulating hepatic bile flow may be different from that involved in 16, 16-dimethyl PGF2 alpha choleresis. The results of this study indicate that the synthetic PGF2 alpha analog produces a choleretic response not mediated by adenylate cyclase and associated with increased chloride and bicarbonate secretion.     

Biliary excretion of inorganic electrolytes: its role in hepatic bile formation

To define the role of inorganic electrolyte secretion in hepatic bile formation, the effects of secretin, glucagon, and differently structured bile acids on bile flow and composition were studied in the dog, guinea pig, and rat. In the dog and guinea pig, secretin (2.5-10 clinical units X kg-1 X 30 min-1) increased bile flow and bicarbonate concentration in bile, a finding consistent with the hypothesis that the hormone stimulates a bicarbonate-dependent secretion possibly at the level of the bile ductule-duct. In the rat, secretin (5-15 CU X kg-1 X 30 min-1) failed to increase bile secretion. Glucagon (1.25-300 micrograms X kg-1 X 30 min-1) increased bile flow in all the three species, and produced no changes in biliary bicarbonate concentrations in the dog and rat. In the guinea pig, however, glucagon choleresis was associated with an increase in bicarbonate concentration in bile, similar to that observed with secretin. The choleretic activities of various bile acids (taurocholate, chenodeoxycholate, glycochenodeoxycholate, tauroursodeoxycholate, and ursodeoxycholic acid, infused at 30-360 mumol X kg-1 X 30 min-1) were similar in the rat (6.9-7.2 microL/mumol), but different in the guinea pig (11-31 microL/mumol). In the latter species, the more hydrophobic the bile acid, the greater was its choleretic activity. In all instances, bile acid choleresis was associated with a decline in the biliary concentrations of chloride, but with no major change in bicarbonate levels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the neuropeptide,bombesin, in bile secretion.

Since ancient times, bile secretion has been considered vital for maintaining health. One of the main functions of bile secretion is gastric acid neutralization with biliary bicarbonate during a meal or Pavlovian response. Although the liver has many extrinsic and intrinsic nerve innervations, the functional role of these nerves in biliary physiology is poorly understood. To understand the role of neural regulation in bile secretion, our recent studies on the effect of bombesin, a neuropeptide, on bile secretion and its underlying mechanisms will be reviewed. Using isolated perfused rat livers (IPRL) from both normal and 2 week bile duct ligated rats, as well as hepatocyte couplets and isolated bile duct units (IBDU) from normal rat livers, bombesin was shown to stimulate biliary bicarbonate and fluid secretion from bile ducts. Detailed pH studies indicated that bombesin stimulated the activity of Cl-/HCO3- exchanger, which was counterbalanced by a secondary activation of electrogenic Na+/HCO3- symport. Quantitative videomicroscopic studies showed that bombesin-stimulated fluid secretion in IBDU was dependent on Cl- and HCO3- in the media, anion exchanger(s), Cl- and K+ channels, and carbonic anhydrase, but not on the microtubular system. Furthermore, this bombesin response is inhibited by somatostatin but not substance P. Finally, studies of secondary messengers in isolated cholangiocytes and IBDU indicated that bombesin had no effect on intracellular cAMP, cGMP, or Ca++ levels in cholangiocytes. These results provide evidence that neuropeptides such as bombesin can directly stimulate fluid and bicarbonate secretion from cholangiocytes by activating luminal Cl-/HCO3- exchange, but by different mechanisms from those established for secretin. These findings, in turn, suggest that neuropeptides may play an important regulatory role in biliary transport and secretion. Thus, this neuropeptidergic regulation of bile secretion may provide a plausible mechanism for the bicarbonate-rich choleresis seen with meals or Pavlovian response.     

Effect of pentobarbital or urethane on bile secretion and chemical composition of blood in the rabbit

A study was made of the effects of anaesthesia with pentobarbital and urethane on the bile secretion and the chemical composition of the blood of New Zealand rabbits. Neither of the agents was observed to affect arterial pH or pO2, but with urethane pCO2 values decreased significantly. This was associated with a pronounced hyperglycaemia. Bile flow was significantly higher in pentobarbital-anaesthetized animals than in urethane-anaesthetized animals, a phenomenon that can be attributed to a different canalicular flow and that will not be related to differences in the bile-acid-dependent fraction of secretion. Under both anaesthetics, bile sodium concentrations were greater than those found in plasma, which can be explained by the formation of micelles with low osmotic activity. Bile bicarbonate concentrations proved to be greater than those observed in plasma. Plasma calcium concentrations were significantly lower with urethane than with pentobarbital, whereas in bile the situation was reversed; both these aspects are discussed.     

Ion secretion by salt glands of desert iguanas (Dipsosaurus dorsalis)

Unlike the NaCl-secreting salt glands of many birds and reptiles, the nasal salt glands of lizards can secrete potassium as well as sodium, with either chloride or bicarbonate as the accompanying anion. The factors responsible for initiating secretion by the gland and the rates of cation and anion secretion were studied in the desert iguana, Dipsosaurus dorsalis. Lizards were given combinations of ions for several days, and secreted salt was collected daily and analyzed for sodium, potassium, chloride, and bicarbonate. Maximum total cation secretion rate was 4.4+/-0.38 micromol/g/d. Cation secretion ranged from 24% to 100% potassium; even high NaCl loads did not abolish potassium secretion. Maximum bicarbonate secretion was about 0.5 micromol/g/d; chloride was the predominant anion. Secretion rate increased only in response to those treatments that included potassium and/or chloride; sodium ions and other osmotic loads (e.g., sucrose) did not increase secretion. This is in contrast to birds and some other reptiles with salt glands, which initiate NaCl secretion in response to any osmotic load. The specificity of the response of the salt gland of Dipsosaurus may be related to the ecological importance of dietary potassium and chloride for herbivorous desert lizards.     

Fate of aflatoxins B1 and G1 residues during biscuit processing

Effect of biscuit processing on the destruction of aflatoxins B₁ and G₁ with and/or without some commonly leavening agents used namely sodium bicarbonate, ammonium bicarbonate and sodium bisulfite and sodium chloride. It was found that mixing step reduced the concentration of aflatoxins B₁ and G₁ by 80.7% and 82.7%, while the effect of baking step being 28.9% and 21.5%. The effect of mixing was found to be more pronounced than that baking step. The highest destruction effect on aflatoxin B1 was observed by adding a mixture composed of sodium and ammonium bicarbonate and sodium bisulfite followed by sodium chloride, sodium bisulfite, ammonium bicarbonate and/or sodium bicarbonate alone, where the reduction values of toxin after mixing were 93.4,91.9,91.7, 88.8 and 86.6% respectively, while the baking effect ranged 17.2 to 34.5% in the presence of different leaving agents added. Concerning aflatoxin G1; the highest destructive effect of toxin was adsorbed by adding a mixture of sodium and ammonium bicarbonate and sodium bisulfite followed by sodium bisulfite, sodium chloride, ammonium bicarbonate and/or sodium bicarbonate alone since the destruction values of such toxin after mixing were 96.2%, 92.8%, 92.6%, 89.0% and 87.7% respectively, while the baking effect ranged 20.9 to 34.5% in all leavening agents added.     

EFFECTS OF POTASSIUM AND LITHIUM ON SODIUM TRANSPORT FROM BLOOD TO CEREBROSPINAL FLUID

Abstract— The relationship between isotopic sodium entry into cerebrospinal fluid (CSF) from blood and cisternal potassium concentration was studied using ventriculo-cisternal perfusion in the rabbit. The entry of sodium into CSF was separated into 2 components. The fast component was significantly correlated with cisternal potassium concentration during perfusions with a potassium-free artificial CSF. ATPase activity in the homogenised choroid plexus was shown to be sensitive to potassium over a range of concentrations similar to that in the perfusion studies. The results are interpreted as showing a potassium-sensitive entry of ²⁴Na across the choroid plexus due to a sodium-pump situated in the apical membrane of the choroid plexus. The effects of low concentrations of lithium (0.6–1.2 mm) on ²⁴Na entry into CSF and brain and on CSF secretion were studied. When applied via the ventricles lithium caused a 30–39% stimulation of the fast component of sodium entry and a 28% stimulation of CSF secretion. When given via the blood lithium inhibited the fast component of sodium entry and CSF secretion by 43% and 40% respectively. No effects of lithium were found on the slow component of sodium entry into CSF or sodium entry into brain. The results suggest that lithium at low (0.6–1.2 mM) concentrations can stimulate the choroid plexus sodium-pump at the potassium-sensitive side and inhibit it at the sodium-sensitive side.     

Carnitine and carnitine esters in rat bile and human duodenal fluid

The recent discovery of carnitine and its esters in rat bile has led to much speculation about its role. The objectives of these studies were to investigate the origin of carnitine esters in rat bile and to study the presence of carnitine in human bile-rich duodenal fluid. Bile was collected from chow-fed (n = 11), fasted (72 h, n = 6), and fasted plus 2-tetradecylglycidic acid administered (72 h, n = 5) male adult rats under sodium pentobarbital anaesthesia. Carnitine and carnitine ester content was measured in the bile and compared with serum and liver carnitine. Bile from fed rats was found to contain 80% acylcarnitine, one-third of this as long chain carnitine esters. Fasting caused no change in the secretion rate of acylcarnitine into the bile, although long chain carnitine ester secretion almost doubled. Conversely, 2-tetradecylglycidic acid treatment caused a decrease in long chain carnitine ester secretion into bile. Duodenal fluid was collected from patients with suspected cholelithiasis (n = 10) before and after pancreozymin-cholecystokinin injection. Although carnitine concentration was variable, it was consistently 80% esterified. These data associate bile carnitine with hepatic carnitine metabolism and establish the presence of carnitine and carnitine esters in the human intestinal lumen.     

Urinary-blood delta PCO2 in renal tubular acidosis (author's transl)

A state of renal tubular acidosis has been produced in rats by the administration of sodium maleate or acetazolamide (proximal tubular acidosis) and of lithium chloride of amiloride (distal tubular acidosis). During progressive alkaline diuresis, delta PCO2 (urine minus blood PCO2) increases significantly in rats presenting proximal tubular acidosis. Delta PCO2 is significantly depressed in rats presenting distal tubular acidosis. In well defined conditions of bicarbonate or phosphate excretion, delta PCO2 is a valuable index of distal ion secretion.     

Spontaneous and bile salt stimulated bile secretion in the Adelie penguin (Pygoscelis adeliae).

The flow rate and ionic composition of bile during spontaneous secretion were measured in anaesthetized penguins in which the enterohepatic circulation had been interrupted and with i.v. injection of saline to replace secretory loss. During the first two hours the rate of flow increased, and then remained relatively constant for a further two and a half hours. During this time the concentration of bile salt fell, but the concentrations of other ions showed small fluctuations only. Sodium taurocholate increased the rate of bile flow and the excretion of ions, except that of bicarbonate. Sodium taurolithocholate initially produced cholestasis but later apparently increased bile flow and had an overall choleretic effect. It is suggested that the active excretion of bicarbonate ions by the bile ducts is the predominant regulator of bile secretion in the penguin.     

Studies of feedback suppression of bile salt synthesis in the bile-fistula rat

We have previously reported that intravenous infusion of taurocholate at 10 mumol (100 g.hr) into bile-fistula rats suppressed bile salt synthesis by 85% (Pries et al. 1983. J. Lipid Res. 24: 141-146). Recently, however, infusion rates twice this high have been reported not to suppress synthesis (Davis et al. 1984. Falk Symposium 42. MTP Press Ltd., Boston. 37-45). Because the only major difference in design of these two studies was supplementation with sodium bicarbonate to replace biliary losses induced by bile salt choleresis, we have repeated our studies with and without bicarbonate supplementation. Without bicarbonate, as before, we found suppression of synthesis during infusion of taurocholate at 10 mumol/(100 g.hr). With bicarbonate, no suppression of synthesis occurred at these infusion rates. These data indicate that bicarbonate supplementation is essential when testing physiological effects of infused bile salt in the bile-fistula rat.     

Taurocholic acid feeding prevents tumor necrosis factor-alpha-induced damage of cholangiocytes by a PI3K-mediated pathway

Cholangiopathies, such as primary biliary cirrhosis and primary sclerosis cholangitis, are characterized at the end stage by ductopenia due to increased cholangiocyte apoptosis and decreased cholangiocyte proliferation. Although cholangiocyte proliferation is associated with an increased number of intra-hepatic bile ducts and secretin-stimulated ductal secretion, ductopenia is coupled with decreased ductal mass and secretin-induced ductal secretory activity. We have shown that a single injection of actinomycin D + tumor necrosis factor-alpha (TNF-alpha ) to bile duct-ligated (BDL) rats induces cholangiocyte injury, which is characterized by loss of cholangiocyte proliferation, and secretory activity and by an increase in cholangiocyte apoptosis. We also have shown that taurocholic acid both in vivo and in vitro stimulates cholangiocyte proliferation. We hypothesize that taurocholic acid feeding protects cholangiocytes against TNF-alpha -induced apoptosis through a phosphatidylinositol-3-kinase (PI3K)-dependent pathway. Immediately after BDL, rats were fed taurocholic acid or control diet in the absence/presence of daily injections of wortmannin for 1 week. Seven days later, control-fed or taurocholic acid-fed rats were treated with a single intraperitoneal injection of actinomycin D + TNF-alpha . Twenty-four hours later we evaluated: (i) cholangiocyte apoptosis and proliferation in liver sections and (ii) basal and secretin-stimulated bile and bicarbonate secretion in bile fistula rats. Taurocholic acid feeding prevented TNF-alpha -induced increases in cholangiocyte apoptosis and decreases in growth and secretin-stimulated bile and bicarbonate secretion, changes that were blocked by PI3K inhibition. The PI3K survival pathway is important in bile acid protection against immune-mediated cholangiocyte injury in cholestatic liver diseases.     

Influence of lithium on biliary electrolyte and bile acid excretion in young and adult rats

The influence of a three-day lithium treatment on the biliary electrolyte and bile acid output was determined in 20- and 105-day-old rats. The osmolarity of bile and the biliary concentrations of cations (Na+, K+, Ca++, H+) and chloride were higher in untreated young rats than in adults, although bile flow and bile acid excretion rates of the young and adult animals were comparable. Lithium increased the biliary excretion of sodium, potassium and calcium and decreased the excretion of chloride and bicarbonate ions in both age groups. In contrast, lithium treatment reduced bile acid excretion only in adult rats. The lithium-induced alterations in biliary ion elimination may be caused by an intracellular replacement of sodium and/or potassium. These results indicate that after lithium treatment cation loss occurs in the young as well as in the adult organism not only via urine and faeces but also via bile.