Rapid diagnosis of Zellweger syndrome and infantile Refsum's disease by fast atom bombardment--mass spectrometry of urine bile salts

A method is described for the rapid determination of urinary bile salt profiles by fast atom bombardment--mass spectrometry (FAB-MS). Urine was passed through a reverse-phase octadecylsilane bonded silica cartridge and the bile salts eluted with methanol. Negative ion FAB spectra could be obtained from the equivalent of 10 microliter of urine loaded onto the target probe with glycerol as matrix. In samples from normal infants and children bile salt peaks were rarely detectable above the background whereas peaks produced by steroid sulphates and glucuronides and bile alcohol glucuronides could usually be identified. In samples from infants and children with cholestasis the major peaks were produced by the taurine and glycine conjugates of di-, tri- and tetrahydroxycholanoic acids (and their monosulphates). In samples from patients with Zellweger syndrome and infantile Refsum's disease, a unique ion at m/z 572 indicated the presence of taurine-conjugated tetrahydroxy-cholestanoic acid(s). The amide linkage to taurine was cleaved by alkaline hydrolysis but not by cholylglycine hydrolase. Capillary gas chromatography--mass spectrometry (GC-MS) of the bile acids liberated by alkaline hydrolysis indicated the presence of at least two nuclear-tetrahydroxylated cholestanoic acids, probably the 6 alpha- and 1 beta-hydroxylated derivatives of 3 alpha, 7 alpha, 12 alpha-trihydroxy-5 beta-cholestan-26-oic acid.     

Bile acid synthesis and excretion following release of total extrahepatic cholestasis by percutaneous transhepatic drainage

Abstract. Urinary, biliary and serum bile acids were studied in three patients before and after percutaneous transhepatic drainage for total bile duct obstruction.
Before drainage high urinary excretion often different bile acids occurred. The percentage distribution was: cholic and chenodeoxycholic acid (66–86%), hyo-cholic (3–16%), 3β 12α-dihydroxy-5-cholenoic (3–6%) and 3β-hydroxy-5-cholenoic acid (2–8%). These acids were regularly found in serum. In addition small amounts (less than 2%) of norcholic, allocholic, 3β, 7α-dihydroxy-5β-cholanoic, 3α, 7α-dihydroxy-5α-cholanoic and lithocholic acid were excreted in urine. Trace amounts of these bile acids were found in serum.
After start of drainage biliary bile acid excretion increased rapidly during the first day, dropped to a minimum during the second or third day and then slowly increased again. In spite of normal volumes of bile produced, the total serum bile acids and the urinary excretion of bile acids remained increased during a drainage period of 19 days. The bile acids were of the same type as observed during cholestasis. In serum the increase was mainly due to high concentrations of chenodeoxycholic and 3β-hydroxy-5-cholenoic acid, as sulphate esters.
Glycine and taurine conjugates of cholic, chenodeoxycholic and hyocholic acid were mainly excreted in bile. Bile acid sulphate esters were only present in trace amounts in bile and were mainly excreted in urine. This, combined with low renal clearance, explains the elevated serum levels of sulphate esters of chenodeoxycholic and 3β-hydroxy-5-cholenoic acid conjugates.     

Delta 4-3-oxosteroid 5 beta-reductase deficiency described in identical twins with neonatal hepatitis. A new inborn error in bile acid synthesis.

A new inborn error in bile acid synthesis, manifest in identical infant twins as severe intrahepatic cholestasis, is described involving the delta 4-3-oxosteroid 5 beta-reductase catalyzed conversion of the key intermediates, 7 alpha-hydroxy-4-cholesten-3-one and 7 alpha,12 alpha-dihydroxy-4-cholesten-3-one for chenodeoxycholic and cholic acid synthesis, to the respective 3 alpha-hydroxy-5 beta (H) products. This defect was detected by fast atom bombardment ionization-mass spectrometry from an elevated excretion and predominance of taurine conjugated unsaturated hydroxy-oxo-bile acids. Gas chromatography-mass spectrometry confirmed these to be 7 alpha-hydroxy-3-oxo-4-cholenoic and 7 alpha,12 alpha-dihydroxy-3-oxo-4-cholenoic acids (75-92% of total). Fasting serum bile acid concentrations were greater than 37 mumol/liter; chenodeoxycholic acid was the major bile acid, but significant amounts of allo(5 alpha-H)-bile acids (approximately 30%) were present. Biliary bile acid concentration was less than 2 mumol/liter and consisted of chenodeoxycholic, allo-chenodeoxycholic, and allo-cholic acids. These biochemical findings, which were identical in both infants, indicate a defect in bile acid synthesis involving the conversion of the delta 4-3-oxo-C27 intermediates into the corresponding 3 alpha-hydroxy-5 beta(H)-structures, a reaction that is catalyzed by a delta 4-3-oxosteroid-5 beta reductase enzyme. This defect resulted in markedly reduced primary bile acid synthesis and concomitant accumulation of delta 4-3-oxo-and allo-bile acids. These findings indicate a pathway in bile acid synthesis whereby side chain oxidation can occur despite incomplete alterations to the steroid nucleus, and lend support for an active delta 4-3-oxosteroid 5 alpha-reductase catalyzing the conversion of the delta 4-3-oxosteroid intermediates to the respective 3 alpha-hydroxy-5 alpha(H)-structures.     

Identification and quantitative determination of urinary bile acids excreted in cholestasis

The monohydroxy bile acids, 3β-hydroxy-5-cholenoic acid and lithocholic acid and the dihydroxy bile acid, ursodeoxycholic acid have been identified by means of combined gas chromatography-mass spectrometry in urine of patients suffering from acute hepatitis, obstructive jaundice and intermittent jaundice, due to cholelithiasis. The occurrence of these bile acids in obstructive jaundice is suggested to be due to primary hepatic synthesis, since deoxycholic acid, the most sensitive indicator for the enterobacterial metabolism of bile acids, failed to be detected in significant quantities in the urine of these patients. The decrease of the content of deoxycholic acid in the urinary bile acid fraction seems to be of diagnostic value in recognition of complete obstruction. The total daily excretion of bile acids with the urine correlates with the degree of cholestasis, as could be judged from comparisons with serum bilirubin values. The occurrence of 3β-hydroxy-5-cholenoic acid seems to reflect an altered sterol metabolism in cholestasis.     

Urinary bile acids in late pregnancy and in recurrent cholestasis of pregnancy

The metabolic profiles of urinary bile acids in pregnant women in the last trimester and patients with recurrent intrahepatic cholestasis of pregnancy (RCP) were studied. Following separation according to mode of conjugation, about thirty different bile acids were quantitatively analysed by gas chromatography-mass spectrometry. In all patients the sulphate fraction comprised 50--90% of the total bile acids. In RCP a shift from glycine to taurine conjugation was noted to together with a slight relative increase in sulphation. A ten- to hundred-fold increase in cholic and chenodeoxycholic acids was seen in RCP, the increase being mainly in the sulphate fraction. Tetrahydroxylated bile acids, tentatively regarded as 1- and 6-hydroxylated products of cholic acid, were quantitatively important in patients with RCP. The relative amounts of the secondary bile acids, deoxycholic and lithocholic acids, decreased with increasing cholestasis. Metabolites hydroxylated at C-6 were common, and the excretion of hydroxylated at C-6 were common, and the excretion of hyocholic acid was positively correlated to that of chenodeoxycholic acid. An increase in the excretion of 5 alpha-configurated bile acids in RCP was noted. A positive correlation between the excretion of 3 beta-hydroxy-5-cholenoic acid and 3 beta,12 alpha-dihydroxy-5-cholenoic acid indicates a metabolic relationship between the two compounds. Because of the relatively small amounts of lithocholic and 3 beta-hydroxy-5-cholenoic acids in patients with RCP, these compounds do not seem to be of pathogenetic importance in this type of cholestasis.     

Equilibration of labelled and endogenous bile acids in patients with liver cirrhosis after administration of (24-14C)cholic and chenodeoxycholic acids

On separate occasions (24-14C)cholic acid and (24-14C)chenodeoxycholic acid were administered intravenously to patients with liver cirrhosis and the isotope excretion in urine and faeces monitored. Bile acids in serum, urine and faeces were extracted and separated into unconjugated bile acids, glycine- and taurine conjugates, glucuronides and sulphates. Individual bile acid conjugates were separated by high-performance liquid chromatography (HPLC) and the unconjugated bile acids were separated by gas-liquid chromatography (GLC) and identified by gas chromatography-mass spectrometry (GC-MS). Individual bile acid conjugates were quantified and their isotope contents determined. In serum, isotope contents declined rapidly during the first day, followed by a markedly slow rate of reduction. In accordance with this, the excretion of isotope from the patients was found to be very slow and the routes of bile acid excretion were changed, which resulted in an increased ratio of urine/faeces isotope excretion. Studies of the ratio of labelled to endogenous bile acid conjugates indicated that a continuous transformation of the labelled compounds occurred during the period of study. As judged from serum bile acids, conjugation to glycine- or taurine conjugates was rapid. The specific activities of labelled sulphate esters were consistently lower than for other conjugates during the 300-min observation period. During the first day, the urinary bile acids contained a high proportion of unconjugated labelled bile acids, which gradually disappeared. Labelled primary bile acids were slowly converted into microbial products, mainly 7-alpha dehydroxylated derivatives. The observed slow transformations resulted in a much delayed equilibration of labelled and endogenous bile acid derivatives, which invalidates isotope techniques for calculation of kinetic data of bile acid turnover. However, the observed very slow turnover of labelled bile acids in cirrhosis, owing to the persistent high rate of intestinal absorption and low capacity for urinary excretion, makes it possible for the intestinal flora to markedly change the composition of the bile acids in the pool. Studies of endogenous urinary and faecal bile acid excretion revealed the changed route of bile acid excretion with a high urinary/faeces ratio and the decreased synthesis of bile acids in cirrhosis.     

The nature of urinary bile acid conjugates in patients with extrahepatic cholestasis

Urinary bile acids from patients with extrahepatic cholestasis were extracted with Sep-pak C18 cartridges and group separated on diethylaminohydroxypropyl Sephadex LH-20. The nature of the different conjugates of cholic and chenodeoxycholic acid in the fractions was studied after further separation by preparative thin-layer chromatography. The free and glycine-conjugated bile acids were quantified by capillary gas chromatography and identified by gas chromatography-mass spectrometry (GC/MS). Taurine conjugates were split with cholylglycine hydrolase and the liberated free bile acids analysed by GC/MS. Sulphate esters were hydrolysed with Helix pomatia and the resulting bile acid derivatives were analysed as above. After hydrolysis with cholylglycine hydrolase, the glucuronides of the unconjugated bile acids were separated and identified by GC/MS. Amino acid analysis of the different fractions revealed that glycine and taurine were the only amino acids present in connection with cholic and chenodeoxycholic acid. Large amounts of monosulphated bile acid conjugates were present but no disulphates. Only 3-sulphates were found. Both sulphates and glucuronides were found exclusively as glycine or taurine conjugates and no such derivatives of unconjugated bile acids were isolated. The isolated conjugates were split either by a combination of acid solvolysis and alkaline hydrolysis or by Helix pomatia and cholylglycine hydrolase.     

Fasting and postprandial serum bile acid concentration with special reference to variations in the conjugate profile

Serum bile acids were group-separated by ion exchange chromatography on diethylaminohydroxypropyl Sephadex LH-20 into unconjugated bile acids and bile acids conjugated with either glycine, taurine, glucuronic acid or sulphuric acid. The conjugate moiety was hydrolysed by treatment with a combination of Helix pomatia and cholylglycine hydrolase and the released bile acids analysed by gas liquid chromatography/mass spectrometry. Analysis of fasting and postprandial serum from six healthy subjects showed that, in addition to the primary bile acids, cholic (C) and chenodeoxycholic acid (CDC), secondary bile acids were present to varying extents. Unconjugated serum bile acids were found in four of the six subjects. Glycine and taurine conjugates of C and CDC and their glucuronides and sulphates were found in all subjects. The postprandial increase of serum bile acids was mainly due to increase of the glycine conjugates of C and CDC. After the meal, the ratio C:CDC in glycine and taurine conjugates shifted to lower values.     

Serum bile acid composition in patients with cystic fibrosis

Serum bile acid composition was examined in detail using capillary column gas chromatography and mass spectrometry in 10 children with cystic fibrosis (CF) and 4 healthy children. The mean total bile acid concentration in fasting serum of CF patients was 2.33 +/- 0.84 mumol/l, slightly lower than but not statistically significantly different from healthy controls (mean 2.86 +/- 0.98 mumol/l) and appeared to show no relationship to the degree of exocrine pancreatic insufficiency. Analysis of individual serum bile acids in these children showed that cholic acid represented less than 10% of the total bile acids. Chenodeoxycholic acid was the predominant serum bile acid; the mean concentration in CF patients was 0.98 +/- 0.51 mumol/l, lower than for the healthy controls (1.69 +/- 0.84 mumol/l). Concentrations of lithocholic acid, 3 beta-hydroxy-5-cholenoic, ursodeoxycholic and 3 beta, 7 alpha, 12 alpha-trihydroxy-5 beta-cholanoic acids in fasting serum samples of the CF patients were not significantly different from the healthy control sera but were higher than those normally found in adults. Measurements of fecal bile acid excretion indicated an increased loss of primary bile acids in patients with CF consistent with an impairment of the enterohepatic circulation of bile acids.     

Identification of a new inborn error in bile acid synthesis: mutation of the oxysterol 7alpha-hydroxylase gene causes severe neonatal liver disease.

We describe a metabolic defect in bile acid synthesis involving a deficiency in 7alpha-hydroxylation due to a mutation in the gene for the microsomal oxysterol 7alpha-hydroxylase enzyme, active in the acidic pathway for bile acid synthesis. The defect, identified in a 10-wk-old boy presenting with severe cholestasis, cirrhosis, and liver synthetic failure, was established by fast atom bombardment ionization-mass spectrometry, which revealed elevated urinary bile acid excretion, a mass spectrum with intense ions at m/z 453 and m/z 510 corresponding to sulfate and glycosulfate conjugates of unsaturated monohydroxy-cholenoic acids, and an absence of primary bile acids. Gas chromatography-mass spectrometric analysis confirmed the major products of hepatic synthesis to be 3beta-hydroxy-5-cholenoic and 3beta-hydroxy-5-cholestenoic acids, which accounted for 96% of the total serum bile acids. Levels of 27-hydroxycholesterol were > 4,500 times normal. The biochemical findings were consistent with a deficiency in 7alpha-hydroxylation, leading to the accumulation of hepatotoxic unsaturated monohydroxy bile acids. Hepatic microsomal oxysterol 7alpha-hydroxylase activity was undetectable in the patient. Gene analysis revealed a cytosine to thymidine transition mutation in exon 5 that converts an arginine codon at position 388 to a stop codon. The truncated protein was inactive when expressed in 293 cells. These findings indicate the quantitative importance of the acidic pathway in early life in humans and define a further inborn error in bile acid synthesis as a metabolic cause of severe cholestatic liver disease.     

Biliary bile acids in uncomplicated pregnancy and in cholestasis of pregnancy

Conjugated and sulfated bile acids were determined by gas-liquid chromatography and by high-pressure liquid chromatography in gallbladder bile samples of four pregnant women at term and of two patients with cholestasis of pregnancy. In healthy pregnant women the mean ratio of cholyl/chenodeoxycholyl/deoxycholyl glycine was 3.7 : 1 : 0.23 and that of taurine conjugates 3.0 : 1 : 0.25, respectively. In gallbladder bile pool of non-pregnant females these ratios were 1.0 : 1 : 0.00 and 1.0 1 : 0.70, respectively. Thus cholic acid predominated in pregnancy bile. In patients with cholestasis of pregnancy, cholid acid comprised 90% of total biliary bile acids, the proportion of chenodeoxycholic acid was greatly decreased and nonsulfated deoxycholic acid was not detected. The proportion of sulfated bile acids of total biliary bile acids was between 0.4 and 1.2% in uncomplicated pregnancy and 0.3 and 0.5% in cholestasis patients.     

Biotransformation of orally administered ursodeoxycholic acid in man as observed in gallbladder bile, serum and urine

Abstract. The aim of this study was to evaluate the biotransformation of orally administered ursodeoxycholic acid in man. The distribution of ursodeoxycholic acid and its metabolites in gallbladder bile, in serum and in urine with emphasis on separation of their unconjugated, amidated and sulfated species in particular, was investigated. Seven gallstone patients were given 750 mg of ursodeoxycholic acid daily for 2–3 weeks. Six gallstone patients who did not receive ursodeoxycholic acid served as controls. Ursodeoxycholic acid became the major bile acid in gallbladder bile contributing 43% to total bile acids. 2% of biliary ursodeoxycholic acids were in the unconjugated form, 87% in the amidated form and 11% in the sulfated form. Iso-ursodeoxycholic acid was found in bile in small amounts and was present only as the sulfated species and not as the amidated one. Other metabolites of ursodeoxycholic acid tentatively identified in bile were 1β, 12β, 6α- and 21,22-hydroxylated derivatives of ursodeoxycholic acid. Lithocholic acid in bile tended to increase under ursodeoxycholic acid treatment and was positively correlated to ursodeoxycholic acid. The concentration of cholic acid in bile decreased significantly whereas the levels of deoxycholic acid and chenodeoxycholic acid did not change. Total bile acid concentration in serum and excretion of bile acids in urine increased from 5.4 ± 1.1 to 18.4 ± 9.5 μmol l^-1 (mean ± SD, P < 0.005) and from 5.6 ± 1.3 to 13.1 ± 7.9 μmol g^-1creatinine (mean ± SD, P < 0.05) after ursodeoxycholic acid ingestion mainly due to spillover and excretion of ursodeoxycholic acid. Ursodeoxycholic acid became the major bile acid in serum and urine contributing 46% and 50% to total bile acids. 14% ursodeoxycholic acid in serum were in the unconjugated form, 42% in the amidated form and 45% in the sulfated form; the percentages in urine were 11%, 23% and 66%. Iso-ursodeoxycholic acid was higher in serum and urine than in bile and contributed 16% and 8% to total bile acids. Iso-ursodeoxycholic acid was present in serum and urine only as the unconjugated and sulfated species. Other iso-bile acids and 3β-hydroxy-5-cholenoic acid were found in bile only in traces, but contributed 8% to total bile acids in serum and 10% in urine. In serum and urine the sulfated form of lithocholic acid prevailed and was significantly enhanced after ursodeoxycholic acid ingestion. Further metabolites of ursodeoxycholic acid in urine were tentatively identified to be hydroxylated at postitions 1β, 5α, 6α and 22 and contributed about 10–15% of urinary UDCA.     

An enzymatic method of determining 7 alpha-hydroxylated bile acids in urine

A recently developed enzymatic method of determining unsulphated 7 alpha-hydroxylated bile acids in serum was evaluated for the analysis of bile acids in urine after hydrolysis of the sulphate esters. Results obtained using the enzymatic method were compared to those obtained by radioimmunoassay of 7 alpha-hydroxylated bile acids in urine samples from patients. Results of the enzymatic method were also compared to results of gas-liquid chromatography of individual bile acids after group separation of the bile acids on Sephadex-DEAP-LH-20. There was significant correlation between the enzymatic method and radioimmunoassay for bile acid determination in urine. The analysis of different conjugates after group separation of bile acids revealed no unspecific reactions when compared to gas-liquid chromatography. The reference range for 7 alpha-hydroxylated urinary bile acids was in agreement with earlier published results.     

Lack of 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase/isomerase in fibroblasts from a child with urinary excretion of 3 beta-hydroxy-delta 5-bile acids. A new inborn error of metabolism.

Cultured fibroblasts were shown to be capable of catalyzing the conversion of 7 alpha-hydroxy-cholesterol to 7 alpha-hydroxy-4-cholesten-3-one, an important reaction in bile acid synthesis. The apparent Km was approximately 7 mumol/liter and Vmax varied between 3 and 9 nmol/mg protein per h under the assay conditions used. The assay was used to investigate fibroblasts from a patient who presented with a familial giant cell hepatitis and who was found to excrete the monosulfates of 3 beta, 7 alpha-dihydroxy-5-cholenoic acid and 3 beta, 7 alpha, 12 alpha-trihydroxy-5-cholenoic acid in urine (Clayton, P. T., J. V. Leonard, A. M. Lawson, K. D. R. Setchell, S. Andersson, B. Egestad, and J. Sj?vall. 1987. J. Clin. Invest. 79:1031-1038). In addition 7 alpha-hydroxy-cholesterol was found to accumulate in the circulation. Cultured fibroblasts from this boy were completely devoid of 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase/isomerase activity. Fibroblasts from his parents had reduced activity, compatible with a heterozygous genotype. The results provide strong evidence for the suggestion that this patient's liver disease was caused by a primary defect in the 3 beta-hydroxy-delta 5-C27-steroid dehydrogenase/isomerase involved in bile acid biosynthesis.     

Bile acid N-acetylglucosaminidation. In vivo and in vitro evidence for a selective conjugation reaction of 7 beta-hydroxylated bile acids in humans.

The aim of this study was to define whether N-acetylglucosaminidation is a selective conjugation pathway of structurally related bile acids in humans. The following bile acids released enzymatically from N-acetylglucosaminides were identified: 3 alpha,7 beta-dihydroxy-5 beta-cholanoic (ursodeoxycholic), 3 beta, 7 beta-dihydroxy-5 beta-cholanoic (isoursodeoxycholic), 3 beta,7 beta-dihydroxy-5 alpha-cholanoic (alloisoursodeoxycholic), 3 beta,7 beta-dihydroxy-5-cholenoic, 3 alpha,7 beta,12 alpha-trihydroxy-5 beta-cholanoic, and 3 alpha,6 alpha,7 beta-trihydroxy-5 beta-cholanoic acids. The selectivity of conjugation was studied by administration of 0.5 g ursodeoxycholic (UDCA) or hyodeoxycholic (HDCA) acids, labeled with 13C, to patients with extrahepatic cholestasis, and of 0.5 g of 13C-labeled chenodeoxycholic acid (CDCA) to patients with extra- or intrahepatic cholestasis. After administration of [24-13C]-CDCA, labeled glucosides, and the glucuronide of CDCA were excreted in similar amounts. Labeled N-acetylglucosaminides of UDCA and isoUDCA were also formed. When [24-13C]-UDCA was given, 13C-label was detected in the N-acetylglucosaminide, the glucosides, and the glucuronide of UDCA, and in the N-acetylglucosaminide of isoUDCA. In the patient studied, 32% of the total UDCA excreted in urine was conjugated with N-acetylglucosamine. In contrast, 96% of the excreted amount of [24-13C]HDCA was glucuronidated, and 13C-labeled glucosides but no N-acetylglucosaminide were detected. The selectivity of N-acetylglucosaminidation towards bile acids containing a 7 beta-hydroxyl group was confirmed in vitro using human liver and kidney microsomes and uridine diphosphate glucose (UDP)-N-acetylglucosamine. These studies show that N-acetylglucosaminidation is a selective conjugation pathway for 7 beta-hydroxylated bile acids.     

Tetrahydroxylated bile acids in healthy human newborns

Urine was collected in four healthy infants, born after 35-39 weeks of gestation. The collections were made for 24 h starting immediately after birth. Bile acids were extracted, separated into conjugate groups, solvolysed, hydrolysed and quantified by gas-liquid chromatography as methyl ester trimethylsilyl ether derivatives. Identification was made by gas-liquid chromatography-mass spectrometry. Cholic acid was the predominating primary bile acid. Non-sulphated tetrahydroxylated bile acids, tentatively identified as 1,3,7,12- and 3,6,7,12-tetrahydroxycholanoic acids, were present in almost the same amounts as cholic acid. A previously unknown tetrahydroxylated cholanoic acid, which might be 2-hydroxylated hyocholic acid, was found in all infants in similar amounts. 3 beta-Hydroxy-5-cholenoic acid was present in the sulphate fraction in the urine from all infants. Lithocholic acid was not found. Small amounts of allo and 6-hydroxylated bile acids were mainly found in the sulphate fraction. Bile acids hydroxylated in the 1-position were found predominantly in the taurine fraction.     

Conjugation, metabolism and excretion of [24-14C] chenodeoxycholic acid in patients with extrahepatic cholestasis before and after biliary drainage-analysis of conjugated bile acids by HPLC

[24-14C] chenodeoxycholic acid (CDC) was given to patients with total extrahepatic cholestasis two or three days before an external drainage was made, and excretion of the isotope in urine and bile followed. Bile acids were group-separated by anion exchange chromatography on DEAP-Sephadex LH-20 and the individual conjugates isolated by HPLC. 51.0-75.4% of the administered isotope was excreted; 16.2-29.9% as sulphates, 0.1-2.4% as glucuronides and 20.7-58.7% as glycine and taurine conjugates. 5.2-21.0% of excreted isotope consisted of transformation products of CDC, mainly cholic acid, hyocholic acid and ursodeoxycholic acid. Labelled urinary sulphates were the 3-sulphates of glycochenodeoxycholic and taurochenodeoxycholic acid. During cholestasis the renal clearance was about ten times higher for the sulphates compared with the non-sulphated conjugate. The clearance of glycine conjugates and their sulphates was of the same magnitude as that of the corresponding taurine conjugates. During the biliary drainage period, most of the labelled sulphates were excreted in urine, while most of the glycine and taurine conjugates were excreted in bile.     

Bile acid profiles in urine of patients with liver diseases

Abstract. Quantitative gas chromatography-mass spectrometry was used to study the metabolic profiles of unconjugated, conjugated and sulphated bile acids in urine of patients with intermittent intrahepatic cholestasis of unknown aetiology, cirrhosis of the liver, primary biliary cirrhosis, viral and toxic hepatitis and extrahepatic cholestasis. A large number of bile acids was present which can broadly be classified into four groups: cholic and chenodeoxycholic acids constituted between 49·4% and 77·9% of the total bile acids (mean values of the groups); deoxycholic and other 3,12-disubstituted bile acids between 1·3% and 12·3%, monohydroxy bile acids between 6·7% and 14·4% and bile acids hydroxylated at C-1 or C-6 between 4·6% and 14·6%. The high proportion of bile acids from the latter group, and the presence of tetrahydroxylated bile acids, clearly distinguished hepatic disease from the normal state. The metabolic profiles were very variable and there were few consistent differences between the groups of diseases studied. Norcholic acid constituted a significantly higher percentage of the total bile acids in cirrhotic patients (6·2 ± 6·8%) than in non-cirrhotic patients (1·3±1·8%, P<0·001). With this exception, no profile was specific for any type of intra- or extra-hepatic cholestasis. The excretion rates of the major l-hydroxylated bile acids were positively correlated to each other. The same was true for the major 6-hydroxylated bile acids. This may indicate that cholic, chenodeoxycholic and deoxycholic acids act as substrates for common 1- and 6-hydroxylating enzymes. Possibly the taurine conjugates are preferred substrates since 1-hydroxylated bile acids and hyocholic acid were found mainly in this fraction. A positive correlation between the excretion of sulphated 3β-hydroxy-5-cholenoic acid and 3β,12α-dihydroxy-5-cholenoic acid indicates a direct metabolic relationship between these compounds. Confirming previous data, a high proportion of bile acids was sulphated. The degree of sulphation increased with decreasing number of hydroxyl groups, reaching 100% for the monohydroxy and most of the dihydroxy acids. Tetrahydroxycholanoates were not sulphated, and sulphation of trihydroxycholanoates was positively correlated to the renal bile acid excretion rate. Bile from patients with intermittent intrahepatic cholestasis did not contain the tetrahydroxylated bile acids present in urine. Hyocholic acid was a very minor, mainly taurine conjugated, bile acid. Monohydroxy bile acids were usually below the detection limit. These data do not support the hypothesis that lithocholic acid participates in the initiation or perpetuation of intermittent intrahepatic cholestasis of unknown aetiology.     

Evidence for renal control of urinary excretion of bile acids and bile acid sulphates in the cholestatic syndrome

1. The bile acids and bile acid sulphates in the urine, serum and bile of eight cholestatic patients were studied quantitatively by gasliquid chromatography and gas-liquid chromoatography/mass spectrometry. 2. The primary bile acids (cholic acid and chenodeoxycholic acid) comprised on average 94% of the total bile acids in bile, 70% in the serum and 64% in urine. 3. The percentage composition of bile acids in bile was relatively constant and was not influenced by the degree of cholestasis. In contrast, in the serum only the primary bile acids were increased, the concentrations of the secondary bile acids (deoxycholic acid and lithocholic acid) and the minor bile acids remaining constant. 4. The data do not support the hypothesis that monohydroxy bile acids accumulate in cholestasis and are related to the pathogenesis of this syndrome. 5. The pattern of bile acid urinary excretion was similar to that in the serum. But in one patient, 3alpha, 7beta, 12alpha-trihydroxy-5beta-cholan-24-oic acid was a principal urinary bile acid, although very low concentrations of the compound were found in that patient's serum, suggesting that some of the minor bile acids in urine may originate by epimerization in the kidney. 6. In bile only a small proportion of the bile acids was sulphated (range 2.1-4.6%) and in serum the degree of sulphation was very variable (9-50%). However, in urine, sulphate esters accounted for a large proportion of the total bile acids (33-72%). 7. The output of bile acid sulphate in the urine was related to the urine total bile acid output but the serum concentration of bile acid sulphate remained relatively constant. Consequently, in contrast to the non-sulphated bile acids, whose renal clearance was relatively constant, the renal clearance of sulphated bile acids was directly related to the urine total bile acid output. This finding is inconsistent with the earlier hypothesis that their predominance in urine was due to a high renal clearance. It may indicate renal synthesis of some of the bile acid sulphates in the urine and/or inhibition of active renal tubular reabsorption of sulphated bile acids by non-sulphated bile acids.     

Bile acids in plasma of patients without kidneys

Bile acids were measured in plasma of three non-fasting bilaterally nephrectomized patients in chronic haemodialysis. After separation of the bile acid mixture according to mode of conjugation and cleavage of amide and sulphate ester bonds, the bile acids were analysed as their methylester trimethylsilyl ethers on gas-liquid chromatography-mass spectrometry (GC-MS). The total bile acid concentration was 4.10-13.70 mumol X l(-1) (N: less than 14 mumol X l(-1)) mostly glycine conjugates. Unconjugated bile acids were found in significant amounts in one patient and in trace amounts in another patient. Chenodeoxycholic acid was the predominant individual bile acid constituting 1.89-6.79 mumol X l(-1) (N: less than 10 mumol X l(-1)). The oxidoreduction product of this bile acid: ursodeoxycholic acid, was found in all patients, whereas the 7 alpha-dehydroxylation product: lithocholic acid, was absent. 1 beta-hydroxy-deoxycholic acid was a major constituent in two of the cases. Hyocholic acid, the 6 alpha-hydroxylation product of chenodeoxycholic acid was detected in two cases. Tetrahydroxy bile acids and sulphated bile acids were not found in significant amounts.