Diagnostic value of serum primary bile acids in detecting bile acid malabsorption.

Serum cholic and chenodeoxycholic acid conjugates were measured in fasting conditions and after meals in 14 patients with bile acid malabsorption due to ileal resection. Mean serum fasting levels of both primary bile acids did not differ from the controls. After meals, serum cholic acid peaks were lower in patients with ileal resection than in control subjects (p less than 0.001), while chenodeoxycholic acid peaks were reduced in colectomised patients (p less than 0.01). In the sera from patients with ileal resection, the glycine/glycine + taurine ratio for cholic and chenodeoxycholic acid increased (p less than 0.001) from morning to evening, and glycine/glycine + taurine ratio for chenodeoxycholic acid was significantly (p less than 0.01) different from the controls in the sera collected in the evening. The results are consistent with the concept of a better intestinal conservation of chenyl, mainly of the glycine conjugated from, than of cholylconjugates, in patients with ileal resection; this is probably because of passive absorption in the intestine. The postprandial peaks of serum cholic acid conjugates may therefore be regarded as a test of ileal dysfunction, while peaks of chenodeoxycholic acid conjugates suggest colonic impairment.     

Delta 4-3-oxosteroid 5 beta-reductase deficiency: failure of ursodeoxycholic acid treatment and response to chenodeoxycholic acid plus cholic acid.

BACKGROUND--In some infants with liver disease, 3-oxo-delta 4 bile acids are the major bile acids in urine, a phenomenon attributed to reduced activity of the delta 4-3-oxosteroid 5 beta-reductase required for synthesis of chenodeoxycholic acid and cholic acid. These patients form a heterogeneous group. Many have a known cause of hepatic dysfunction and plasma concentrations of chenodeoxycholic acid and cholic acid that are actually greater than those of the 3-oxo-delta 4 bile acids. It is unlikely that these patients have a primary genetic deficiency of the 5 beta-reductase enzyme. AIMS--To document the bile acid profile, clinical phenotype, and response to treatment of an infant with cholestasis, increased plasma concentrations of 3-oxo-delta 4 bile acids, low plasma concentrations of chenodeoxycholic acid and cholic acid, and no other identifiable cause of liver disease. PATIENTS--This infant was compared with normal infants and infants with cholestasis of known cause. METHODS--Analysis of bile acids by liquid secondary ionisation mass spectrometry and gas chromatography-mass spectrometry. RESULTS--The plasma bile acid profile of the patient was unique. She had chronic cholestatic liver disease associated with malabsorption of vitamins D and E and a normal gamma-glutamyltranspeptidase when the transaminases were increased. The liver disease failed to improve with ursodeoxycholic acid but responded to a combination of chenodeoxycholic acid and cholic acid. CONCLUSION--Treatment of primary 5 beta-reductase deficiency requires the use of bile acids that inhibit cholesterol 7 alpha-hydroxylase.     

Bile acid metabolism in non-jaundiced patients with malignant liver tumours

Bile acids were determined in the serum and urine of four non-jaundiced patients with secondary liver tumours by means of gas-liquid chromatography. In serum only the concentration of cholic and chenodeoxycholic acids were increased in two of the patients. The renal excretion of cholic and/or chenodeoxycholic acids was increased in all patients, whereas the excretion of hyocholic acid was increased in two. The renal excretion of 3 beta-hydroxy-5-cholenic acid was not increased in any of of the patients. One patient with multiple liver metastases was studied during the development of jaundice. During this period there was an increase of serum concentrations and renal excretion both of unsulphated cholic, hyocholic, and chenodeoxycholic acids and of sulphated chenodeoxycholic and 3 beta-hydroxy-5-cholenic acids. One non-jaundiced patient with a primary liver tumour, a hepatocarcinoma, had almost normal serum concentrations and renal excretion of bile acids.     

Ursodeoxycholic acid administration on bile acid metabolism in patients with early stages of primary biliary cirrhosis

Ursodeoxycholic acid has been proposed for the treatment of primary biliary cirrhosis. The aim of this study was to evaluate the effect of ursodeoxycholic acid administration on bile acid metabolism in patients with early-stage primary biliary cirrhosis. Biliary bile acid composition, primary bile acid pool sizes, synthesis, and fractional turnover rate were measured before and after four weeks of ursodeoxycholic acid administration (600 mg/day) in nine patients with biopsy-proven primary biliary cirrhosis (stages I-III). Molar percentages of chenodeoxycholic, cholic, and deoxycholic acids in bile were significantly decreased by ursodeoxycholic acid administration, while its biliary concentration increased to 34.2% at the end of the same four-week period. The cholic and chenodeoxycholic acid pools decreased, although not significantly, while the deoxycholic acid pool was reduced by 60% (from 0.7±0.12 to 0.29±0.07 mmol,P<0.002). Primary bile acid synthesis was slightly increased, and fractional turnover rate was significantly increased. The conversion rate of cholic to deoxycholic acid was measured and found to be significantly increased (P<0.05) after ursodeoxycholic acid administration; however, serum levels of both free and conjugated deoxycholic acid were significantly decreased (from 23.2±9.7 to 3.8±1.9 μmol/liter,P<0.001). We conclude that in patients with primary biliary cirrhosis, ursodeoxycholic acid administration replaces endogenous bile acids in the enterophepatic circulation by increasing bile acid fractional turnover rate without significant increments of their hepatic synthesis.     

Bile acid metabolism in human hyperthyroidism

Decreased levels of serum cholesterol are a well-recognized finding in hyperthyroidism. Since the conversion to bile acids is an important pathway for the elimination of cholesterol, we studied primary bile acid kinetics in seven hyperthyroid patients before and after medical treatment. Pool sizes, fractional turnover and synthesis rates of cholic acid and chenodeoxycholic acid were determined after oral administration of 50 mg [13C]cholic acid and 50 mg [13C]chenodeoxycholic acid. 13C/12C isotope ratios in serum were measured by capillary gas chromatography/electron impact mass spectrometry. Compared with the euthyroid state, serum cholesterol levels were distinctly lower in hyperthyroidism (150 +/- 33 vs. 261 +/- 51 mg per dl, p less than 0.01). Thyroid hormone excess caused a 34% reduction in cholic acid synthesis (5.8 +/- 2.8 vs. 7.9 +/- 4.2 mu moles per kg per day, p less than 0.02), which was associated with a 47% decrease in cholic acid pool size (11.7 +/- 3.4 vs. 22.0 +/- 5.2 mu moles per kg, p less than 0.01). Chenodeoxycholic acid kinetics exhibited no apparent changes. Thus, total primary bile acid synthesis was diminished by 20% in hyperthyroidism. After normalization of thyroid function, the ratio of cholic acid/chenodeoxycholic acid pool size increased in all patients. This was paralleled by a rise in the ratio of concentrations of cholic acid/chenodeoxycholic acid in serum. The depression of cholic acid synthesis in the presence of unaltered subjects is compatible with an inhibition of hepatic 12 alpha-hydroxylation by thyroid hormone. Furthermore, evidence is provided that, in man, the low serum cholesterol levels found during hyperthyroidism are not caused by an increased conversion of cholesterol to bile acid.     

Acute effects of ursodeoxycholic and chenodeoxycholic acid on the small intestinal absorption of bile acids

The effects of ursodeoxycholic acid and chenodeoxycholic acid on the small-intestinal absorption of endogenous bile acids were studied in patients with ileostomies who served as a model to investigate small-intestinal absorption in humans. In the control period, the eight patients excreted 327 +/- 91 (mean +/- standard error of the mean) mumol/8 h cholic acid and 214 +/- 38 mumol/8 h chenodeoxycholic acid by their ileal fluid. Following ursodeoxycholic acid administration (500 mg), ileal excretion of cholic acid increased to 517 +/- 96 mumol/8 h, and that of chenodeoxycholic acid increased to 337 +/- 42 mumol/8 h, indicating decreased absorption of these bile acids. Following chenodeoxycholic acid administration (500 mg), no significant increase of cholic acid excretion was observed, whereas chenodeoxycholic acid excretion increased as expected. It is concluded that following ursodeoxycholic acid administration the absorption of common bile acids from the small intestine decreases markedly. This effect of ursodeoxycholic acid on intestinal absorption of common bile acids probably is responsible for the decrease of their plasma concentrations, the reduction of their pool sizes, the increase of their fractional turnover rates, and most likely also contributes to the increased hepatic synthesis of cholic acid.     

Sequential changes in serum levels of individual bile acids in patients with chronic cholestatic liver disease

In order to determine the value of serum bile acids in predicting the course of chronic cholestatic liver diseases, we measured individual serum bile acids serially, using high-performance liquid chromatography, over a 4 year observation period in 12 patients with primary biliary cirrhosis and six patients with primary sclerosing cholangitis. The changes in individual serum bile acids and the ratios thereof, conventional liver tests and Child-Turcotte and Mayo scores were compared between survivors (n= 10) and patients who underwent liver transplantation for (n= 3) or died of the liver disease (n= 5). Patients with a serum total chenodeoxycholic acid concentration at study entry that exceded 15 μmol/L were 10 times more likely to die or need a liver transplant in the following 4 years than those with chenodeoxycholic acid levels < 15 μmol/L (P < 0.05). None of the other biochemical parameters or clinicopathological scores could similarly discriminate between the two groups at entry. Time-dependent analyses for the cholic acid/chenodeoxycholic acid ratio, serum total bilirubin and albumin concentrations and Child-Turcotte and Mayo scores were able to differentiate between primary sclerosing cholangitis patients who died or were transplanted and those who were not, whereas age of the patients and other parameters did not. The taurocholic acid /taurochenodeoxycholic acid ratio fell during progression of primary biliary cirrhosis but rose in temporal relationship with primary sclerosing cholangitis. This differential pattern of change was unique compared with other clinical and laboratory indices. In conclusion, serum chenodeoxycholic acid levels and the cholic acid /chenodeoxycholic acid ratio in both diseases were independent indices that allowed for the prediction of survival or the need for liver transplantation. These indices are worthy of further examination in a larger group of patients as prognostic criteria for chronic cholestatic liver disease and in the assessment of the efficacy of therapeutic interventions, including liver transplantation.     

Altered bile acid metabolism in primary biliary cirrhosis

Selected aspects of bile acid metabolism were assessed in six women with primary biliary cirrhosis and varying degrees of cholestasis. Urinary bile acid excretion was markedly increased and correlated highly with serum levels. In three patients in whom urinary bile acids were separated by chromatography, the majority of urinary bile acids were monosulfated (34%, 42%, 32%) or polysulfated and/or glucuronidated (30%, 20%, 38%). The monosulfates of chenodeoxycholic acid were conjugated at either the 3 position (67%, 68%, 73%) or the 7 position (33%, 32%, 27%); similarly, the monosulfates of cholic acid were conjugated at the 3 position (65%, 58%, 68%) or the 7 position (35%, 42%, 32%). The position of sulfation was not markedly influenced by the mode of amidation with glycine or taurine. Chenodeoxycholic exchangeable pool size, turnover rate, and synthesis were measured by isotope dilution and found to be well within normal limits, despite the cholestasis. The fraction of chenodeoxycholic acid synthesis excreted in urine ranged from 9 to 48%; 4–38% of chenodeoxycholic acid synthesis was sulfated. These data indicate that the major abnormalities in bile acid metabolism in patients with cholestasis secondary to primary biliary cirrhosis are formation of sulfated bile acids in greatly increased amounts, elevation of blood levels of primary bile acids, and a shift to renal excretion as a major mechanism for bile acid elimination. Chenodeoxycholic acid synthesis continues at its usual rate despite cholestasis. Whether these changes, including the formation of 7-monosulfated bile acids, occur in other forms of cholestasis and whether either the persistance of unchanged chenodeoxycholic acid synthesis or the formation of such novel conjugates has any pathophysiological significance remain to be investigated.Supported by NIH grant AM 21506 to the University of California and grant RR 00585 and NIH grants AM 19448 and AM 16770 to the Mayo Clinic and Mayo Foundation. In addition, research at the University of California was supported by grants-in-aid from the Rorer Company, the Eli Lilly Company, and the Canada Packers Limited Company.     

The Patterns of Glycine and Taurine Conjugates of Bile Acids in Serum in Hepatobiliary Disease

Fasting serum concentrations of glycine and taurine conjugates of cholic, chenodeoxycholic, and deoxycholic acid were measured with a high-pressure liquid chromatography-enzymatic assay in patients with hepatobiliary disease. The total glycine to taurine ratio was significantly lower in extrahepatic cholestasis (median 1.1) than in cirrhosis (median, 2.0) and controls (median, 1.7). In patients with cirrhosis the ratio was significantly correlated with the S-bilirubins, P-coagulation factors (II + VII + X), and S-total conjugated bile acids. Because of large overlaps of the ratio between the groups the glycine to taurine ratio is of hardly any diagnostic value. The ratio of cholic acid conjugates to chenodeoxycholic acid conjugates was over 1.5 in 10 of 12 cholestasis patients and below this value in all but 1 patient with cirrhosis; the separation of the groups was not improved by splitting the ratio in glycine and taurine conjugates. This study does not suggest that separate determination of glycine and taurine conjugates of bile acids in serum adds diagnostic information in hepatobiliary disease.     

Portal venous bile acids in cholesterol gallstone disease: effect of treatment with chenodeoxycholic and cholic acids

We determined the serum concentrations of cholic, chenodeoxycholic and deoxycholic acids in portal and peripheral venous blood in 9 gallstone-free patients and 39 patients with cholesterol gallstones during standardized cholecystectomy. An accurate and specific gas chromatographic-mass spectrometric technique was used. The portal venous concentration of total bile acids was similar in gallstone-free and untreated gallstone patients (n = 20); there was no evidence of a reduced hepatic uptake of bile acids in the latter. Treatment with cholic acid (n = 10) was associated with a 70% increase in cholic acid and normal concentration of total bile acids. In chenodeoxycholic acid-treated patients (n = 9), the portal venous concentration of this bile acid was increased 3-fold; total bile acids were increased about 60%. The estimated hepatic uptake of cholic acid was slightly decreased during chenodeoxycholic acid treatment. The results indicate that neither bile acid inflow to the liver nor hepatic bile acid uptake is reduced in fasting patients with cholesterol gallstones, and treatment with chenodeoxycholic acid increases fasting inflow of bile acids to the liver. The latter may contribute to unsaturation of fasting hepatic bile during treatment with chenodeoxycholic acid.     

Endogenous ursodeoxycholic acid and cholic acid in liver disease due to cystic fibrosis

Focal biliary cirrhosis causes significant morbidity and mortality in cystic fibrosis (CF). Although the mechanisms of pathogenesis remain unclear, bile acids have been proposed as potential mediators of liver injury. This study examined bile acid composition in CF and assessed altered bile acid profiles to determine if they are associated with incidence and progression of liver injury in CF-associated liver disease (CFLD). Bile acid composition was determined by gas-liquid chromatography/mass spectrometry in bile, urine, and serum samples from 30 children with CFLD, 15 children with CF but without liver disease (CFnoLD), and 43 controls. Liver biopsies from 29 CFLD subjects were assessed histologically by grading for fibrosis stage, inflammation, and disruption of the limiting plate. A significantly greater proportion of endogenous biliary ursodeoxycholic acid (UDCA) was demonstrated in CFnoLD subjects vs. both CFLD subjects and controls (2.4- and 2.2-fold, respectively; ANOVA, P =.04), and a 3-4 fold elevation in endogenous serum UDCA concentration was observed in both CFLD subjects and CFnoLD subjects vs. controls (ANOVA, P <.05). In CFLD, there were significant correlations between serum cholic acid and hepatic fibrosis, inflammation, and limiting plate disruption as well as the ratio of serum cholic acid/chenodeoxycholic acid to hepatic fibrosis, inflammation, and limiting plate disruption. In conclusion, elevated endogenous UDCA in CFnoLD suggests a possible protective role against liver injury in these patients. The correlation between both cholic acid and cholic acid/chenodeoxycholic acid levels with histological liver injury and fibrosis progression suggests a potential monitoring role for these bile acids in CFLD.     

Influence of cholic and chenodeoxycholic acid on canalicular bile flow in man.

Hepatic bile flow was measured and hepatic [(14C]mannitol clearance was calculated during depletion of the bile acid pool and during duodenal administration of cholic or chenodeoxycholic acid in 10 patients 7 to 12 days after operation for uncomplicated gallstone disease. The relationship between [(14)C]mannitol clearance and bile flow was linear, with a regression coefficient which was not significantly different from unity. This finding supported the assumption that mannitol clearance can be used as a measure of canalicular bile flow in man. Linear relationships between bile acid secretion rate and bile flow and bile acid secretion rate and [(14)C]mannitol clearance were found during depletion of the bile acid pool (secretion of cholic, chenodeoxycholic, and deoxycholic acids; relative concentrations, 1.0:1.0:0.5) as well as during cholic acid infusion (73 +/- 3% cholic acid in the secreted hepatic bile) and during chenodeoxycholic acid infusion (88 +/- 2% chenodeoxycholic acid in the secreted hepatic bile). The bile flow dependence on bile acids 0.011 +/- 0.002 ml mumoles(-1)) was not significantly different for "mixed" bile acid secretion, mainly cholic acid secretion, or mainly chenodeoxycholic acid secretion. Neither was the ductular bile flow (0.08 +/- 0.03 ml min(-1)) significantly influenced by the various experimental conditions. The canalicular flow--the bile acid-independent (0.17 +/- 0.05 ml min(-1)) and the bile acid-dependent flow--constituted 70 to 85% of the total bile flow. It is concluded that secretion of cholic acid and of chenodeoxycholic acid promote the same bile flow volume per micromole in man.     

Benign recurrent intrahepatic cholestasis: altered bile acid metabolism

Altered bile acid metabolism has been claimed to play a role in the etiology of benign recurrent intrahepatic cholestasis (BRIC). Therefore, we studied bile acid metabolism in detail in 10 patients with this syndrome. Pool sizes of both primary bile acids were estimated simultaneously, using deuterated cholic acid and chenodeoxycholic acid. The pool sizes of cholic acid and chenodeoxycholic acid, expressed in micromoles per kilogram body weight, were significantly contracted in BRIC patients during a cholestasis-free period: 8.0 +/- 4.2 and 11.7 +/- 4.7, respectively, versus 24.1 +/- 11.7 and 22.9 +/- 7.8 in controls. Fractional turnover rates (per day) for cholic acid and chenodeoxycholic acid were increased: 0.70 +/- 0.29 and 0.58 +/- 0.27, respectively, versus 0.29 +/- 0.12 and 0.23 +/- 0.10 in controls. Bile acid pool composition expressed as percentages in BRIC patients was cholic acid 34 +/- 17, chenodeoxycholic acid 38 +/- 9, deoxycholic acid 27 +/- 18, and lithocholic acid 1 +/- 1, with a glycine to taurine conjugation ratio of 6.7 +/- 4.9. Corresponding values for 32 controls were cholic acid 57 +/- 13, chenodeoxycholic acid 29 +/- 9, deoxycholic acid 14 +/- 9, and lithocholic acid less than 1, with a glycine to taurine conjugation ratio of 2.4 +/- 1.3. Fecal bile acid loss, in micromoles per kilogram body weight per day, was 11.2 +/- 9.0 in BRIC patients compared with 2.8 +/- 1.4 in controls. The serum 7 alpha-hydroxycholesterol level (nanomoles per liter) was significantly increased in BRIC patients: 326 +/- 179 versus 171 +/- 90 in controls. These results suggest that in BRIC patients spillover of bile acids into the colon occurs, which leads to increased fecal bile acid loss and a reduced bile acid pool size. Increased serum 7 alpha-hydroxycholesterol is probably indicative of an accelerated bile acid synthesis rate due to increased activity of cholesterol 7 alpha-hydroxylase, the enzyme catalyzing the first step in the major pathway of bile acid synthesis. The results of our study suggest that in BRIC patients a contracted bile acid pool increases the susceptibility of the liver for cholestatic agents.     

Bile acids in bile during long-term chenodeoxycholic acid treatment.

Relative concentrations of conjugated and sulfated bile acids in duodenal bile were measured in 5 patients before and during treatment with 0.50-0.75 g of chenodeoxycholic acid per day for 3-4 months. Lithocholic acid constituted 0.8-3.3% (mean 1.8%) of total conjugated and sulfated bile acids before and 0-5.4% (mean 2.6%) during treatment. Lithocholic acid was the predominant bile acid in the sulfate fraction in three patients and chenodeoxycholic acid in two. Sulfated bile acids constituted less than 1% of total bile acids and did not increase during treatment. Ursodeoxycholic acid, the other major metabolite of chenodeoxycholic acid, was found in higher amounts during therapy. The unsaturated bile acid 3beta-hydroxy-delta5-cholenic acid, which was found exclusively as its sulfate ester, showed a slight fall. The average G/T conjugation ratio rose from 2.2 to 4.5.     

Effect of ursodeoxycholic acid on bile acid metabolism in primary biliary cirrhosis

We have compared the effect of ursodeoxycholic acid with placebo on the clinical state, blood liver chemistries and serum and urinary bile acids in four patients with primary biliary cirrhosis. All parameters were evaluated monthly, and bile acid composition was measured by capillary gas-liquid chromatography. At the time of admission, all patients showed intense pruritus, and their serum alkaline phosphatase, AST and ALT levels were elevated 4.3, 2.7 and 2.3 times over control values. Serum bile acids were elevated almost 38-fold with 2.5 times more cholic acid than chenodeoxycholic acid. Urinary bile acid output was elevated 28 times the control values, and 36% were 1 beta-hydroxycholic acid, 1 beta-hydroxydeoxycholic acid and hyocholic acid (3 alpha,6 alpha, 7 alpha-trihydroxy-5 beta-cholanoic acid). Three months of placebo administration did not significantly affect the clinical or biochemical presentations, and the serum and urinary bile acid composition did not change. In contrast, ursodeoxycholic acid feeding (12 to 15 mg per kg per day) for 6 months abolished pruritus in two and lessened itching in two subjects and reduced serum alkaline phosphatase, AST and ALT levels by 21, 35 and 47%, respectively. The mean values for the total serum bile acid concentrations in these patients declined 26% from the pretreatment value, but the proportion of ursodeoxycholic acid increased from 3 to 40% of the total bile acids; thus, total fasting serum endogenous bile acid levels decreased almost 50%. Similar changes were noted in the urinary bile acids, in which ursodeoxycholic acid became the major bile acid, and approximately 18% were hydroxylated at C-1, C-6 and C-21.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sulphated and unsulphated bile acids in serum, bile, and urine of patients with cholestasis.

Samples of serum, bile, and urine were collected simultaneously from patients with cholestasis of varying aetiology and from patients with cirrhosis; their bile acid composition was determined by gas/liquid chromatography and mass spectrometry. In cholestasis, the patterns in all three body fluids differed consistently and strikingly. In serum, cholic acid was the major bile acid and most bile acids (greater than 93%) were unsulphated, whereas, in urine, chenodeoxycholic was the major bile acid, and the majority of bile acids (greater than 60%) were sulphated. Secondary bile acids were virtually absent in bile, serum, and urine. The total amount of bile acids excreted for 24 hours correlated highly with the concentration of serum bile acids; in patients with complete obstruction, urinary excretion averaged 71-6 mg/24 h. In cirrhotic patients, serum bile acids were less raised, and chenodeoxycholic acid was the predominant acid. In healthy controls, serum bile acids were consistently richer in chenodeoxycholic acid than biliary bile acids, and no bile acids were present in urine. No unusual monohydroxy bile acids were present in patients with primary biliary cirrhosis, but, in several patients, there was a considerable amount of hyocholic acid present in the urinary bile acids. The analyses of individual bile acids in serum and urine did not appear to provide helpful information in the differential diagnosis of cholestasis. Thus, in cholestasis, conjugation of chenodeoxycholic acid with sulphate becomes a major biochemical pathway, urine becomes a major route of bile acid excretion, and abnormal bile acids are formed.     

Changes in bile acid composition in patients with primary biliary cirrhosis induced by ursodeoxycholic acid administration

We describe a detailed study of the effects of ursodeoxycholic acid administration on bile acid composition of the serum and bile of patients with primary biliary cirrhosis. Gas chromatography-mass spectrometry was used to analyze bile acids from 10 patients with primary biliary cirrhosis before and during ursodeoxycholic acid administration (500 mg/day, corresponding to approximately 8 mg/kg body wt), after group separation of the unconjugated and conjugated fractions by lipophilic anion exchange chromatography. These studies were directed at assessing whether the beneficial role of ursodeoxycholic acid in primary biliary cirrhosis was the consequence of a shift in the hydrophobic/hydrophilic balance of the bile acid pool and whether the hypercholeresis might result from the cholehepatic circulation of unconjugated ursodeoxycholic acid in bile. In basal conditions, the unconjugated bile acids accounted for only 5.5% and 2.5%, respectively, of the total bile acids of serum and bile; cholic acid was the major component of the conjugated fraction of serum and bile (56.0% +/- 4.0%, mean +/- S.E.M.), and ursodeoxycholic acid was present in only trace amounts. The conjugated fraction contained many unusual bile acids (representing 16.5% +/- 1.3% of total) including C25 bile acids, iso-chenodeoxycholic acid and several oxo-bile acids. After ursodeoxycholic acid administration biochemical indices of liver function all improved, but the proportions of the unconjugated bile acids in serum and bile did not significantly change.(ABSTRACT TRUNCATED AT 250 WORDS)     

Abnormal hepatic sinusoidal bile acid transport in an Amish kindred is not linked to FIC1 and is improved by ursodiol

BACKGROUND & AIMS: The mechanism for abnormal hepatic bile acid transport was investigated in an 18-month-old Amish boy who presented with pruritus, poor growth, and severe bleeding episodes. Serum bilirubin, gamma-glutamyltranspeptidase, and cholesterol levels were normal, but prothrombin time and partial thromboplastin time were prolonged and bone alkaline phosphatase level was elevated. METHODS AND RESULTS: Cholic acid plus chenodeoxycholic acid levels measured by capillary gas-chromatography were 32 times higher than control in serum (34.7 vs. 1.1+/-0.4 microg/dL) but were not detected in liver and were reduced in gallbladder bile. Treatment with ursodiol, a more hydrophilic bile acid, improved pruritus, produced 37% weight gain, and after 2 years reduced serum primary bile acid concentrations about 85%, while accounting for 71% of serum and 24% of biliary bile acid conjugates. On ursodiol therapy, hepatic bile acid synthesis was enhanced 2-fold compared with controls, and microscopy revealed chronic hepatitis without cholestasis. Three younger sisters with elevated serum bile acids responded positively to ursodiol. Microsatellite markers for the FIC1 (gene for Byler's disease) region in these 4 children were inconsistent with linkage to FIC1. CONCLUSIONS: Conjugated cholic acid and chenodeoxycholic acid were synthesized in the liver and secreted into bile but could not reenter the liver from portal blood and accumulated in serum. In contrast, unconjugated ursodiol entered the liver and was conjugated and secreted into bile. Thus, the enterohepatic circulation of all conjugated bile acids was interrupted at the hepatic sinusoidal basolateral membrane. Unconjugated ursodiol bypassed the hepatic uptake block to enlarge the biliary and intestinal bile acid pools. A mutation in FIC1 recognized among the Amish and linkage of the disorder to FIC1 were excluded.     

Competition in liver transport between chenodeoxycholic acid and ursodeoxycholic acid as a mechanism for ursodeoxycholic acid and its amidates'' protection of liver damage induced by chenodeoxycholic acid

BACKGROUND: Ursodeoxycholic acid has been widely used as a therapeutic agent in cholesterol gallstones and liver disease patients, but its mechanism of action is still under investigation. AIMS: The protective effect of ursodeoxycholic acid, both free, taurine and glycine conjugated, against hepatotoxic bile acids such as chenodeoxycholic acid and its taurine amidate was studied in bile fistula rats and compared with the cholic and taurocholic acid effect. METHODS: Tauroursodeoxycholic acid, glycine ursodeoxycholic acid, ursodeoxycholic acid, taurocholic acid and cholic acid were infused iv over 1 hour (8 micromol/min/kg) together with an equimolar dose of either taurochenodeoxycholic acid or chenodeoxycholc acid. Bile flow, total and individual bile acid and biliary lactate dehydrogenase and alkaline phosphatase enzymes were measured. RESULTS: Taurochenodeoxycholic acid and chenodeoxycholc acid caused cholestasis and liver damage associated with a decreased bile flow, total and individual bile acids secretion accompanied by a biliary leakage of lactate dehydrogenase and alkaline phosphatase enzymes. Tauroursodeoxycholic acid, glycine ursodeoxycholic acid, ursodeoxycholic acid and taurocholic acid, on the contrary, were choleretic, inducing an opposite effect on biliary parameters. Simultaneous infusion of taurochenodeoxycholic acid and the protective bile acid resulted in a functional and morphological improvement of the above parameters in the following order: glycine ursodeoxycholic acid > tauroursodeoxycholic acid > ursodeoxycholic acid followed by taurocholic acid; cholic acid was ineffective. CONCLUSIONS: The results show the protective effect of glycine ursodeoxycholic acid, ursodeoxycholic acid and tauroursodeoxycholic acid. This may be due to a facilitated transport of the toxic bile acid into bile; conjugation with taurine is less effective than glycine. Finally, the better protective effect of ursodeoxycholic acid and its amidates with respect to cholic acid and its taurine conjugated form seems to be related to their different lipophilicity and micellar forming capacity.     

Serum bile acids in relation to disease activity and intake of dietary fibers in juvenile ulcerative colitis.

Serum concentrations of primary bile acids were determined at different disease activities in juvenile ulcerative colitis and in healthy age-matched controls. In patients with ulcerative colitis in clinical remission, serum levels of bile acids were also studied after long-term intake (6 months) of dietary fibers (wheat fiber and ispaghula, respectively) in a double-blind randomized cross-over study. Blood samples were taken in the morning after an overnight fasting and for 4 h postprandially after a standardized test meal. Determinations of bile acids were made by radioimmunoassays. Patients with total colitis in the active phase had significantly higher serum levels of cholic and chenodeoxycholic acids 4 h postprandially compared with control children. After long-term intake of ispaghula, significantly higher (although not different from controls) serum levels of cholic acid were found 2 and 3 h postprandially, whereas wheat fibers did not affect serum bile acid concentrations. These results may suggest an increased absorption of unconjugated bile acids in the diseased colon and a minimal influence of dietary fibers on serum bile acid concentrations.