Distribution of alkaline sphingomyelinase activity in human beings and animals. Tissue and species differences

The alkaline sphingomyelinase (SMase) was first found in rat intestinal brush border. The important roles of this enzyme in digestion of sphingomyelin and in mucosal cell proliferation have been suggested. In the present work, the distribution of the alkaline SMase in the tissues of human beings and animals have been studied. By assaying the enzyme activity in human biopsy samples, we found that the alkaline SMase activity was absent in the stomach, increased in the duodenum, present at high levels in the small intestine, and slightly declined in the colon and rectum. High activities were found similarly in the intestinal contents of the healthy adults and infants. The activities were also found in the intestinal mucosa of rats, normal and germ-free mice, and hamsters with the same distribution pattern as in humans, but not in the intestinal mucosa of guinea pigs. Apart from the intestinal tract, a SMase activity preferring alkaline pH was identified in human and guinea pig bile, but not in the bile of rat, pig, sheep, and cow. No activity was found in either pancreatic tissue or pancreatic juice in all species tested, and none was detected in human urine and milk. In conclusion, alkaline SMase exists predominantly in the digestive system with considerable tissue and species differences.

Cholylsarcosine, a new bile acid analogue: metabolism and effect on biliary secretion in humans

BACKGROUND

Cholylsarcosine, the synthetic conjugate of cholic acid and sarcosine, is resistant to deconjugation-dehydroxylation during enterohepatic cycling in rodents and improves lipid absorption in a canine model of intestinal bile acid deficiency caused by distal intestinal resection. Experiments were performed to define its metabolism and effect on biliary secretion in humans.

METHODS

The circulating bile acid pool was labeled with [14C]cholylsarcosine, and its turnover rate and biotransformation were determined by sampling bile daily. Cholylsarcosine (or cholyltaurine) was infused into the duodenum for 8 hours to define its effect on bile flow and biliary lipid secretion.

RESULTS

Cholylsarcosine was lost rapidly from the enterohepatic circulation with a t1/2 of 0.5 days. The compound was not biotransformed by hepatic or bacterial enzymes. Cholylsarcosine had choleretic activity similar to that of cholyltaurine but induced more phospholipid and cholesterol secretion than cholyltaurine in four or five subjects. Infusion of cholylsarcosine (or cholyltaurine) at a rate averaging 0.6 mumol.min-1.kg-1 gave a biliary recovery of 0.2 mumol.min-1.kg-1; this value is the Tmax for active ileal transport of conjugated bile acids in humans. Laboratory tests for liver injury remained within normal limits.

CONCLUSIONS

In humans, cholylsarcosine is not metabolized, is nontoxic, and has similar effects on biliary secretion as cholyltaurine. It appears safe to test in long-term studies the effect of cholylsarcosine on bile acid-deficiency states in humans.

Negative feedback regulation of the ileal bile acid transport system in rodents

BACKGROUND

Active transport of conjugated bile acids by ileal enterocytes is a key mechanism for conservation of the bile acid pool. Experiments were performed to determine whether such transport is regulated by substrate load.

METHODS

Using anesthetized biliary fistula guinea pigs or rats, the ileum was perfused with ursodeoxycholyltaurine at a concentration causing maximal ileal transport of this bile acid; absorption was assessed by biliary recovery. Before ileal perfusion, animals ingested one of three diets: chow, chow with added conjugated bile acid, or chow with added cholestyramine.

RESULTS

In the guinea pig, ingestion of a taurocholate-enriched diet resulted in a 75% decrease in the absorption rate of ursodeoxycholyltaurine. Similar results were obtained with cholylsarcosine (a deconjugation-dehydroxylation resistant analogue) or with chenodeoxycholylglycine, the endogenous bile acid of the guinea pig. In contrast, cholestyramine ingestion caused an increase in ursodeoxycholyltaurine absorption. In the rat, cholyltaurine or cholylsarcosine ingestion also caused decreased ileal transport. In the guinea pig, maximal down-regulation of active ileal bile acid transport occurred after 2-3 days of bile acid feeding; up-regulation required 3-4 days.

CONCLUSIONS

Bile acid metabolism is regulated by feedback inhibition of active ileal transport in addition to the well-established feedback inhibition of bile acid biosynthesis in the liver. Together, these two regulatory mechanisms ensure constancy of bile acid secretion.

Effect of cholylsarcosine on hepatic cholesterol and bile acid synthesis and bile secretion in rats

The regulatory and secretory properties of cholylsarcosine (C-sar), a synthetic conjugated bile acid analogue that resists deconjugation and dehydroxylation, were compared with those of the natural conjugates of cholic acid. After continuous intraduodenal infusion of cholylsarcosine (C-sar), cholyltaurine (C-tau), or cholylglycine (C-gly) at 36 mumol/100 g.h, the infused bile acid in each case became the predominant biliary bile acid. After 48 hours, infusion of C-sar, C-tau, and C-gly suppressed the activity of cholesterol 7 alpha-hydroxylase (C7 alpha H; rate-limiting for bile acid synthesis) by 65%, 78%, and 92%, respectively, compared with biliary fistula controls. After C-sar infusion, levels of C7 alpha H protein, messenger RNA, and transcriptional activity were depressed to the same extent as specific activity, indicating that C-sar, like C-tau, down-regulates C7 alpha H principally at the level of gene transcription. All three bile acids also suppressed activity of 3-hydroxy-3-methylglutaryl-coenzyme A reductase (rate-limiting for cholesterol synthesis). Both short- and long-term, the three cholyl conjugates caused similar increases in bile flow and in biliary secretion of cholesterol and phospholipid. It is concluded that in the rat, cholyl conjugates per se can suppress cholesterol and bile acid biosynthesis without prior conversion to deoxycholate. The effects of C-sar on hepatic cholesterol and bile acid synthesis as well as on induced bile flow and biliary lipid secretion are essentially identical to those of the naturally occurring cholyl conjugates.

Acute effects of topical methyl tert-butyl ether or ethyl propionate on gallbladder histology in animals: a comparison of two solvents for contact dissolution of cholesterol gallstones

Experiments were performed in anesthetized rabbits and piglets to assess gallbladder mucosal injury during irrigation with methyl tert-butyl ether, a C5 ether, or ethyl propionate, a C5 ester--two organic solvents used in the contact dissolution of cholesterol gallstones. In 44 New Zealand White rabbits, the gallbladder was exposed to individual solvents or saline solution through a transhepatic catheter for 2 hr. Gallbladders were then harvested and fixed immediately or after a recovery period of 1, 4 or 8 days. Tissue sections were examined under light microscopy, and severity of injury was graded with predefined criteria by two pathologists blinded to the animals' treatment regimens. Histological assessment showed severe mucosal injury such as necrosis of the cells at the villus tips immediately after 2 hr of exposure to either solvent. After 4 days, injury had decreased significantly; after 8 days, complete mucosal healing had taken place. A similar study was performed in 32 piglets. Solvent or saline solution was oscillated in and out of the gallbladders of these piglets with a computer-controlled syringe pump at a pressure less than the leakage pressure of the gallbladder. Histological assessment was performed on tissue samples obtained immediately after the procedure or 8 days later. Both solvents caused severe mucosal injury; however, after 8 days complete mucosal healing had occurred, so that gallbladders exposed to solvent were indistinguishable from gallbladders exposed to saline solution, which was used as control. We conclude that both methyl tert-butyl ether and ethyl propionate cause moderate to severe epithelial injury but that the gallbladder epithelium regenerates within a few days.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of replacement therapy with cholylsarcosine on fat malabsorption associated with severe bile acid malabsorption. Studies in dogs with ileal resection

The efficacy of cholylsarcosine, a synthetic deconjugation-resistant and nonsecretory conjugated bile acid analog for the treatment of fat malabsorption caused by severe bile acid malabsorption, was assessed in an animal model. In two dogs, the ileum and ileocecal valve were resected, causing severe diarrhea, steatorrhea, bile acid malabsorption, and progressive weight loss. Cholylsarcosine was administered as the water-soluble sodium salt by mixing with the dog food. Various doses were explored as well as varying intakes of dog food. Fat absorption was assessed by gravimetric measurement of fecal fat; a nonabsorbable recovery marker (polyethylene glycol mol wt 4000) was used to correct for incomplete fecal collections. Cholylsarcosine caused a 5- to 30-fold increase in fat absorption but had no significant effect on weight loss or fecal weight. Duodenal content was collected during digestion of a meal via a surgically placed Thomas cannula; the aspirates were dilute, acidic, and had a low bile acid concentration. The bile acid concentration increased modestly when cholylsarcosine was administered, but remained below the critical micellization concentration. The results indicate that oral administration of cholylsarcosine improved dietary fat absorption in a canine model of severe bile acid malabsorption with associated steatorrhea and bile acid deficiency in the proximal small intestine. Studies with this compound in patients with nutritional problems because of steatorrhea and severe bile acid malabsorption appear warranted.

Conjugated bile acid uptake by Xenopus laevis oocytes induced by microinjection with ileal poly A+ mRNA

Apical membranes of ileal enterocytes contain the major Na+/bile acid cotransporter activity in mammals. Microinjection of guinea pig ileal mucosal Poly A+ mRNA (25 ng) into Xenopus oocytes resulted in 22,23-3H-cholyltaurine uptake at day 3 after injection (453 fmol/oocyte-hr), while control viral mRNA (25 ng) gave an uptake rate of 133 fmol/oocyte-hr. The transport rate increased in direct relationship to the concentration of injected mRNA, cholyltaurine, or Na+ in the incubation media. Uptake of cholyltaurine using rabbit ileal mucosal Poly A+ mRNA was 3891 fmole/oocyte-hr compared to rabbit jejunal-mucosa Poly A+ mRNA (control) injections inducing 728 fmol/oocyte-hr. Such expression of the ileal Na+/bile acid cotransporter may facilitate cloning of this key mammalian gene.

Physicochemical and physiological properties of cholylsarcosine. A potential replacement detergent for bile acid deficiency states in the small intestine

The properties of cholylsarcosine (the synthetic N-acyl conjugate of cholic acid with sarcosine [N-methylglycine]) were examined to determine its suitability as a bile acid replacement agent for conditions of bile acid deficiency in the small intestine, which causes fat malabsorption. Previous studies in rodents had shown that the compound was well transported by the liver and ileum and underwent neither deconjugation nor dehydroxylation during enterohepatic cycling. By 1H-nuclear magnetic resonance, cholylsarcosine was found to exist in dilute aqueous solution as an almost equimolar mixture of two geometric isomers--cis and trans (around the amide bond)--in contrast to cholylglycine, which was present entirely in the trans form. The critical micellization concentration was 11 mmol/liter, similar to that of cholylglycine (10 mmol/liter). By nonaqueous titrimetry, the pKa' of cholylsarcosine was 3.7, only slightly lower than that of cholylglycine (3.9). Cholylsarcosine was poorly soluble below pH 3.7, but highly soluble above pH 4. In vitro, cholylsarcosine behaved as cholylglycine with respect to promoting lipolysis by lipase/colipase. There was little difference between cholylsarcosine and cholylglycine in their solubilization of an equimolar mixture of oleic acid, oleate, and monoolein (designed to simulate digestive products of triglyceride) or in their solubilization of monooleyl-glycerol alone. When a [3H]triolein emulsion with either cholylsarcosine or cholyltaurine was infused intraduodenally in biliary fistula rats, recovery of 3H in lymph was 52 +/- 10% (mean +/- SD) for cholylsarcosine and 52 +/- 11% for cholyltaurine. When perfused into the colon of the anesthetized rabbit, cholylsarcosine (5 mmol/liter) did not influence water absorption or permeability to erythritol, in contrast to chenodeoxycholate, which induced vigorous water secretion and caused erythritol loss. We conclude that cholylsarcosine possesses the physicochemical and physiological properties required for a suitable bile acid replacement in deficiency states.

Bacterial deconjugation and enterohepatic circulation of norursocholic acid conjugates in rats

Experiments were performed to define the metabolism of norusocholic acid (nUC) conjugates and to quantify to what extent the bile acid pool can be enriched in these bile acids. In vitro incubations of norusocholylglycine (nUCG) and -taurine (nUCT) with small intestinal or cecal content showed deconjugation with only cecal content. Cholylglycine (CG) was deconjugated by small intestinal and cecal content. Infusion of nUCG and CG showed that only a small proportion of nUCG was deconjugated after 24 h of enterohepatic circulation, whereas all CG was deconjugated. When nUCT was administered orally, deconjugation was shown to take place mainly in the cecum. Chronic feeding of nUCT enriched the bile acid pool with only 20% nUCT. We conclude that nUC conjugates are deconjugated primarily by bacteria in the cecum and colon, in contrast to CG, which, in addition to cecum and colon, is deconjugated in the distal small intestine. nUCT and its metabolites do not enrich in the circulating bile acid pool mainly for the following reasons: 1) nUC conjugates have a low affinity for the ileal transport system; 2) nUC, even if formed by deconjugation, is not passively absorbed at a sufficient rate; 3) the small amount of norursodeoxycholic acid formed from nUC is glucuronidated in the liver and glucuronide conjugates do not undergo enterohepatic circulation; and 4) nUC conjugates do not suppress bile acid biosynthesis.

Hepatic and ileal transport and effect on biliary secretion of norursocholic acid and its conjugates in rats

The enterohepatic circulation of norursocholic acid (nUC) and its glycine (nUCG) and taurine (nUCT) conjugates was investigated in the rat; cholic acid (C) was studied as control. The biliary recovery of intravenously infused 14C-labeled bile acids was high: nUC, 88%; nUCG, 80%; nUCT, 99%, and C, 90%. Biliary recovery after the same bile acids were infused intraduodenally was similar: nUC, 90%; nUCG, 66%; nUCT, 97%; and C, 99%. The two conjugated bile acids, nUCG and nUCT, were not biotransformed during intestinal or hepatic transport; nUC was also secreted largely unchanged, but approximately 10% was secreted as an unknown conjugate or sulfate; C was completely conjugated with taurine or glycine. To compare the rates of active ileal transport, biliary recovery was measured after an in situ ileal perfusion technique. The rate of absorption of nUC, nUCG, and nUCT was one-fourth to one-half that of cholyltaurine, which served as control. Competition experiments indicated that the same transport system was involved. When infused intravenously, nUC, nUCG, and nUCT induced far less biliary lipid secretion than an identical dose of C; the secretion of both phospholipid and cholesterol was decreased, cholesterol to a greater extent than phospholipid. It is concluded that nUC and its conjugates are well transported by the ileum, are efficiently secreted into bile without undergoing appreciable hepatic biotransformation, and induce bile flow as other hydrophilic bile acids, but in contrast to C induce little phospholipid and cholesterol secretion into bile.

Activation of mast cells by bile acids

To test whether bile acids interact with mast cells, dilute, aqueous solutions of five pure unconjugated natural bile acids and their corresponding glycine or taurine conjugates were incubated with murine PT-18 cells (a mast cell line functionally and cytochemically similar to mucosal mast cells) or with freshly isolated rat peritoneal mast cells. Bile acid solutions ranged in concentration from 0.3 to 10 mmol/L; histamine release was assessed by a fluorimetric assay, and cell lysis by cytosolic enzyme (lactate dehydrogenase) release. Lipophilic, dihydroxy bile acids (chenodeoxycholic acid and deoxycholic acid as well as their glycine and taurine conjugates) caused histamine release in a dose-related manner; cholic acid and its conjugates caused much less or no histamine release. Two hydrophilic bile acids (ursodeoxycholic acid and ursocholic acid and their conjugates) were virtually devoid of activity. Histamine release, which was independent of extracellular Ca2+, occurred at 0.3 mmol/L, well below the critical micellization concentration. For a given concentration, unconjugated bile acids and glycine-conjugated bile acids induced more histamine release than taurine-conjugated bile acids; maximal release was observed at 3 mmol/L for lipophilic, dihydroxy bile acids. To test whether bile acids could also cause histamine release from cutaneous mast cells in vivo, rats were injected intradermally with bile acid solutions and histamine release assessed by capillary leakage of Evan's blue dye. Cutaneous blueing was greater with cytotoxic bile acids, chenodeoxycholyglycine or deoxycholylglycine, than with ursodeoxycholylglycine and was inhibited by prior antihistamine treatment. Histamine release correlated highly and positively with lipophilicity and with bile acid surface activity. It was concluded that lipophilic but not hydrophilic bile acids possess concentration-dependent cytotoxicity toward mast cells causing histamine release, that unconjugated and glycine-conjugated bile acids are more potent than taurine-conjugated bile acids, and that mast cell histamine release is highly correlated with lipophilicity of bile acids as well as their surface activity.

Biological and medical aspects of active ileal transport of bile acids

The active transport of conjugated bile acids by the ileum is responsible for the enterohepatic circulation of bile acids, a physiological process that ensures an ample supply to the intestine of these key biological surfactants, irrespective of the rate of their biosynthesis from cholesterol. The ileal bile acid transport system is a high capacity, low affinity secondary active Na+ co-transport system that differs in substrate specificity from that present in the hepatocyte. Ileal transport is homeostatically regulated by feedback inhibition of the bile acids that are transported. The enterohepatic circulation is responsible for the concentration profile present in the intestine--high concentrations in the small intestine and low concentrations in the large intestine. Loss of ileal absorption, when mild, leads to a sequence of events that result in increased concentrations in the large intestine causing diarrhea. Severe bile acid malabsorption causes decreased concentrations in the small intestine which in turn lead to fat maldigestion and fat malabsorption. The increased passage of fatty acids into the colon contributes to diarrhea. Fat maldigestion and malabsorption also causes increased absorption of dietary oxalate from the colon which causes hyperoxaluria and contributes to nephrolithiasis. In cholestatic liver disease, inappropriate upregulation of ileal bile acid transport is likely to cause retention of hepatotoxic endogenous bile acids. In familial hypercholesterolemia, efficient bile acid absorption contributes to downregulation of LDL receptors and the maintenance of elevated plasma cholesterol levels; upregulation of bile acid transport during bile acid sequestrant therapy could diminish its efficacy. Efforts are in progress to develop a suitable bile acid analogue to be administered orally for conditions of bile acid deficiency in the small intestine.(ABSTRACT TRUNCATED AT 250 WORDS)

Active absorption of conjugated bile acids in vivo. Kinetic parameters and molecular specificity of the ileal transport system in the rat

Active transport of conjugated bile acids by the distal ileum is required for efficient enterohepatic cycling of bile acids. Experiments were performed in the rat to obtain accurate values for Tmax and Michaelis constant (Km) of the absorptive area of the rat ileum and to define the structural specificity of the transport system. The distal fifth (20 cm) of the small intestine from an anesthetized animal with a biliary fistula was perfused using solutions of 10 taurine-conjugated bile acids; a flow rate was used that was sufficiently high such that unstirred water layer effects were negligible and the intraluminal concentration remained unchanged throughout the perfused segment. The absorption rate was equated with the rate of hepatic bile acid secretion. Values of Tmax (mumol/min.kg) were markedly influenced by bile acid structure: cholyltaurine, 12.9; ursocholyltaurine, 9.6; ursodeoxycholyl taurine, 5.0; and lagodeoxycholyl-(3 alpha,12 beta-dihydroxy-cholanoic acid)-taurine, 1.2. Decreasing the length of the side chain of ursodeoxycholate conjugates from 8 to 6 carbon atoms was associated with a modest increase in Tmax values from 5.0 to 9.1 mumols/min.kg. Values of Km correlated with Tmax values and ranged from 0.5 to 5 mmol/L, being highest for those bile acids that were best transported. The Tmax for cholyltaurine transport was not reached when the intraluminal concentration was as high as its critical micellization concentration, precluding the definition of its Tmax; however, for ursocholyltaurine, with a critical micellization concentration of 40 mmol/L, saturation of transport was clearly shown. Kinetic parameters could not be obtained for two common dihydroxy conjugates (chenodeoxycholyltaurine and deoxycholyltaurine) because at a transport rate of 2 mumols/min.kg systemic toxicity and death occurred. These studies define the maximal transport capacity of the rat ileum for taurine-conjugated bile acids; they indicate that the ileal transport system in the rat is of low affinity and high capacity for taurine conjugates of hydrophilic bile acids, and they show that both nuclear substituents and side chain length influence the transport rate of taurine-conjugated bile acids.

Influence of individual bile acids in Escherichia coli peritonitis

Previous studies have shown that intraperitoneal bile increases bacterial growth and mortality in Escherichia coli peritonitis in the rat. The purpose of the present study was to determine a) the influence of bile acids (cholic, deoxycholic, or chenodeoxycholic) and bilirubin on survival, bacterial growth, and superoxide release by peritoneal phagocytes in this model, and b) the effect of bile acids on bacterial growth and endotoxin release when incubated with E. coli in vitro. Each of the bile acids aggravated the E. coli peritonitis, with increased bacterial counts in the peritoneal cavity and in blood and increased mortality. Deoxycholic acid was the most deleterious of the bile acids, causing suppression of superoxide release by peritoneal phagocytes, like whole bile. In vitro, bile acids did not seem to affect growth of E. coli, but cholic and deoxycholic acid seemed to enhance the release of endotoxin. It is concluded that the bile acids are responsible for the noxious effect of bile in E. coli peritonitis. It is suggested that the detergent properties of bile acids aggravate the peritonitis by solubilizing the cell membranes of both bacteria and phagocytes.

Deconjugation of bile salts: does it occur outside the contents of the intestinal tract in the rat?

Several different methods have been applied to measure the extent of bile salt deconjugation (deamidation), if any, outside the gastro-intestinal tract of the rat. A breath test has been applied to the rat using peroral or intravenous administration of cholyl-glycine-1-14C. Results for normal rats have been compared with rats with a continuous recirculation of bile to a tail vein. Bile salts labelled with 2,4-3H in the sterol moiety and conjugated with glycine-1-14C have been infused in rats and recirculated via a bile duct tail-vein shunt. The 3H:14C ratio in the bile has been used as an indication of deconjugation. In these experiments the radioactivity pattern of the bile salts has been determined after thin-layer chromatography. Different labelled bile salts have also been infused intraperitoneally and the composition of bile secreted through bile fistulae studied. In none of these experiments, in which the gastro-intestinal content was bypassed and a return of bile salts to the liver in the physiological range ensured, was any deconjugation of glycine-conjugated bile salts observed. When the liver, however, was stressed by anaesthesia and the intraportal infusion of deoxycholyl-2,4-3H-glycine in unphysiological levels, deconjugation occurred as indicated by the appearance in bile of labelled taurine conjugates. In these rats the dose of deoxycholylglycine was clearly toxic as evidenced by partial or complete cholestasis and eventually death of the animal.

Effects of cholic acid, 7 beta-hydroxy- and 12 beta-hydroxy-isocholic acid on bile flow, lipid secretion and bile acid synthesis in the rat

The effects of three epimeric trihydroxy-cholanoic acids, cholic acid (C), 7 beta-hydroxy-(7 beta) and 12 beta-hydroxy-(12 beta) isocholic acids on bile flow, lipid secretion, bile synthesis and bile micellar properties were studied in the rat with a bile fistula. The bile salts were infused intraduodenally starting 72 hours after cannulation when endogeneous bile salt synthesis had plateaued after the bile salt pool was drained. The bile salts were infused at two levels approximately 2 and 4 mumol min-1 kg-1. All three bile salts were absorbed and secreted almost quantitatively into the bile. Cholic acid was secreted in the conjugated form, 7 beta conjugated to approximately 60% and 12 beta completely in the unconjugated form. The bile salts did not undergo any significant biotransformations during the one passage from the intestine through the liver. Bile flow increased from the preinfusion level for all three bile salts infused in the order 7 beta greater than 12 beta greater than C. The bile flow increased linearly with bile salt secretion more for 7 beta than for C and 12 beta. Infusion of C increased the secretion into bile of phospholipid (PL) and cholesterol (CH) over the preinfusion values. Infusion of 7 beta as well as 12 beta resulted in a parallel decrease in the secretion of PL as well as CH compared to the preinfusion values. The infusion of C and 7 beta at the two levels used decreased the secretion of newly synthesized bile salt below the control level.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of feeding ursocholic acid to germfree rats

Germfree rats were fed 24-14C-ursocholic acid (UC) mixed into the diets for 10 days. The bile was then drained by cannulation for 6 hours to collect the bile salt pool. No biotransformation of the labelled UC occurred and it constituted approximately equal to 75% of an enlarged bile salt pool. Less phospholipid and cholesterol were secreted into the bile per mumol bile salt compared to normal rats. The critical micellar concentration (CMC) of the bile was determined by equilibrium dialysis and found to be increased. Faecal excretion of labelled triolein added to the diet was unaffected by feeding ursocholic acid. Excretion of 14C-octadecane and 14C-cholesterol increased significantly under the same conditions. Ursocholic acid feeding thus resulted in a selective malabsorption of octadecane and cholesterol.