New concepts in bilirubin and jaundice: report of the Third International Bilirubin Workshop, April 6-8, 1995, Trieste, Italy.

The workshop covered three major areas: Unconjugated bilirubin (UCB) chemistry and physical chemistry; UCB transport and intracellular trafficking; and evaluation and therapy of neonatal and congenital hyperbilirubinemias. Findings of studies in the chemistry and physical chemistry area were as follows. (1) Nuclear magnetic resonance (NMR) studies of highly enriched 13COOH mesobilirubin in water-dimethyl sulfoxide systems indicated that the pKa values of the carboxyl groups are 4.2 and 4.9, respectively. This finding differs from some reports that suggest that the two pKa values in aqueous systems are near or above pH 7.0. (2) Contrasting views of the hydrophobic interactions of UCB with bile salts were presented: one suggested that multiple bile salt monomers bind to one UCB molecule; the other suggested that UCB binds to the nonpolar surface of helical bile salt micelles. (3) Structures were proposed for the varied calcium and copper bilirubinate salts formed at various pH values and cation/UCB ratios. (4) Studies of binding of UCB to human serum albumin (HSA) showed marked diminution of UCB-binding affinity as albumin and chloride concentrations increased. (5) A unique UCB derivative, bilirubin-C10-sulfonic acid, was identified as the major bile pigment in bullfrog bile. (6) New methods were presented for removal of impurities from preparations of bile salts and UCB. Findings of studies in the transport area were as follows. (1) Four putative basolateral and two putative canalicular hepatocytic transporters of UCB and related organic anions were described. Special emphasis was given to the adenosine triphosphate (ATP)-dependent canalicular multi-specific organic anion transporter that is defective in three strains of mutant rats with congenital conjugated hyperbilirubinemia. (2) The roles of the classical and newer molecular biological approaches to identification of these transporters were contrasted, and their limitations were discussed. (3) The relative roles of the multiple carriers in UCB transport under different conditions and substrate concentrations were discussed. (4) Cytosolic UCB-binding proteins (e.g., ligandin) were shown to promote transcellular movement of UCB by solubilizing and transporting the pigment in the aqueous phase while limiting binding of UCB to the relatively immobile membranes of cell organelles. (5) Mechanisms were presented for translocation of UDP-glucuronic acid (UDPGA) into the lumenal location of UDPGA transferase in the endoplasmic reticulum, as well as the enhancement of this process by N-acetyl-glucosamine. Studies in the neonatal and congenital jaundice area were as follows. (1) Criteria were reviewed for initiating treatment of neonatal jaundice, emphasizing the primacy of serum bilirubin levels, gestational age, and hemolysis as risk factors for kernicterus. (2) New methods were presented for frequent, automated monitoring of serum bilirubin levels and breath CO levels as an index of rates of formation of UCB from heme. (3) The current status and limitations of new approaches to treatment of severe unconjugated hyperbilirubinemia were discussed: hepatocyte transplantation and gene therapy, still in the stage of development in animal models, have provided only partial and temporary relief of hyperbilirubinemia; extracorporeal liver assist devices have had some success in initial human studies; and inhibition of heme oxygenase (HO) with metalloporphyrins, especially tin mesoporphyrin, which markedly decreases bilirubin production for prolonged periods, is a new alternative to phototherapy. (4) The ontogeny of the two HO isozymes was contrasted in the liver, spleen, kidney, and lung.

Effect of combined treatment with 2,3,7,8-tetrachlorodibenzo-p-dioxin and phototherapy on bilirubin metabolism in the jaundiced Gunn rat.

2,3,7,8-Tetrachlorodibenzo-p-dioxin, a potent inducer of microsomal cytochrome P448-dependent monoxygenases, and phototherapy both accelerate bilirubin metabolism and decrease jaundice in Gunn rats. The effects of combined treatment with 2,3,7,8-tetrachlorodibenzo-p-dioxin and light were studied in these rats by applying phototherapy for 65 hr, beginning 5 days after induction with 2,3,7,8-tetrachlorodibenzo-p-dioxin. 2,3,7,8-Tetrachlorodibenzo-p-dioxin pretreatment caused a 75% decline in plasma bilirubin in 5 days, with no change thereafter, whether or not the rats were exposed subsequently to phototherapy. In the uninduced rats, plasma bilirubin levels declined by 55% after 40 hr of phototherapy. As determined by [14C]bilirubin kinetics, both 2,3,7,8-tetrachlorodibenzo-p-dioxin and phototherapy increased fractional bilirubin turnover and decreased the total bilirubin pool. In the 2,3,7,8-tetrachlorodibenzo-p-dioxin-induced rats, the contracted bilirubin pool shifted from skin to liver, but these tissue pools did not change further during phototherapy. By contrast, in uninduced rats, phototherapy decreased the cutaneous bilirubin pool, which is the main target of phototherapy. 2,3,7,8-Tetrachlorodibenzo-p-dioxin was more effective than phototherapy in diminishing plasma bilirubin levels and the total bilirubin pool, but the combined treatment (2,3,7,8-tetrachlorodibenzo-p-dioxin followed by phototherapy) was no more effective than 2,3,7,8-tetrachlorodibenzo-p-dioxin alone.

Effects of phototherapy on the activity of microsomal mixed-function monooxygenases and the pharmacokinetics of [14C] hexobarbital in jaundiced and heterozygous Gunn rats.

We assessed the effects of in vivo phototherapy of Gunn rats on the activity of hepatic microsomal mixed-function monoxygenases and on the in vivo pharmacokinetics of [14C]HB. In experiment 1 no serial changes were seen in activities of hexobarbital hydroxylase or benzo(a)pyrene hydroxylase in hepatic microsomes isolated after 2, 4 or 7 days from homozygous jaundiced female Gunn rats exposed to continuous phototherapy or in matched Gunn rats maintained under dim light. In experiment 2 homozygous jaundiced (jj) and heterozygous nonjaundiced (Jj) Gunn rats of both sexes each received i.v. [14C]HB on 2 successive days. In random order, each was exposed on the first or second day to phototherapy for 5.5 hr, beginning 0.5 hr before the administration of HB; otherwise, each was kept under dim light. Plasma [14C]HB in arterial blood samples was separated chromatographically from its labeled metabolites, and biexponential plasma disappearance curves for [14C]HB were analyzed by a SAAM-23 computer program. Clearances in female rats were much slower. In both sexes, the total body clearance and volume of distribution of HB were decreased by 20% during phototherapy of the jj but not the Jj rats; terminal plasma half-life was unchanged. In experiment 3 direct in vitro illumination of [14C]HB did not cause photodegradation of this compound, despite the presence of albumin with or without bilirubin.

Pruritus in hepatic cholestasis. Pathogenesis and therapy.

Pruritus associated with hepatic cholestasis may cause significant morbidity. Current evidence indicates that bile acids may not be the pruritogenic factor. Rather, the factor may be some other cholephilic anion or anions that bind to cholestyramine resin and are photolabile. Effective treatment modalities used currently include cholestyramine resin and phenobarbital. Phototherapy is a promising modality in which the mechanism and most effective wavelengths remain to be elucidated. Analysis of the possible role of non-steady state bile acid compartmentalization in the pathogenesis of pruritus is presented.

Effects of phenobarbital on bilirubin metabolism and its response to phototherapy in the jaundiced Gunn rat.

Jaundiced Gunn rats, treated with phenobarbital (60 mg per kg i.p. for 7 to 10 days) showed 25 and 36% decreases in mean plasma bilirubin levels in two experiments (p less than 0.01). Kinetic studies with tracer 14C-bilirubin revealed that there was no change in bilirubin turnover or total pool size due to phenobarbital, but a 49% increase in the hepatic pool and a 27% decrease in the cutaneous pool of bilirubin. The increase in the hepatic pool accounted for over 90% of the bilirubin lost from the plasma. Such pretreatment with phenobarbital did not alter the decline in plasma bilirubin or total bilirubin pool due to subsequent phototherapy. Phenobarbital followed by phototherapy produced a significantly greater reduction in plasma bilirubin levels than either treatment alone. These studies demonstrate that phenobarbital does decrease plasma bilirubin in Gunn rats primarily by shifting the pigment to the liver, and suggests that combined treatment with phenobarbital and phototherapy might be of value in patients with congenital hyperbilirubinemia due to glucuronyl transferase deficiency.

The effect of elimination of environmental light on the metabolism of unconjugated bilirubin in the Gunn rat.

In the homozygous jaundiced Gunn rat, bilirubin catabolism is augmented by intense illumination (phototherapy) and by induction of microsomal cytochrome P448. To assess the relative importance of less intense environmental light versus intrinsic mechanisms in the maintenance of bilirubin turnover, Gunn rats were kept for three weeks under either ordinary laboratory lighting (0.3-0.8 mW/cm2, wavelength range 400-600 nm) or in absolute darkness. No differences in plasma concentration, miscible pool, turnover of bilirubin, or in hepatic cytochrome P448 activity were noted between the two groups over this period. A greater than twofold increase in the biliary excretion of unconjugated bilirubin was noted in the animals maintained under light, but this represented only 2% of total bilirubin turnover. These results suggest that intrinsic(enzymatic ?) pathways are of primary importance in the maintenance of bilirubin metabolism in the glucuronyltransferase-deficient state under ordinary levels of environmental light.

Excretion of administered and endogenous photobilirubins in the bile of the jaundice gunn rat.

Radiolabeled photobilirubins, prepared in vitro by anaerobic illumination of [34C]bilirubin, were injected intravenously into homozygous jaundiced Gunn rats with an external bile fistula. With the animals kept in darkness, the labeled photobilirubins were excreted rapidly in bile. Photobilirubins IA and IB were excreted primarily as unconjugated bilirubin, whereas photobilirubin II was excreted primarily as photobilirubin II and not converted into bilirubin. Bile of Gunn rats given no exogenous pigments, but undergoing phototherapy, contained a large proportion of photobilirubin II and, if collected in liquid nitrogen, traces of photobilirubins I; neither was found in bile when these rats were kept in the dark. Because there is prior evidence that these rats were kept in the dark. Because there is prior evidence that these photobilirubins are isomers of bilirubin, these experiments indicate that the major mechanism of phototherapy is photoisomerization of bilirubin. Photobilirubin II is the unidentified major photoderivative described previously, whereas formation of photobilirubins IA and IB, and their reversion to bilirubin-IXalpha, account for the remarkably increased output of the parent pigment during phototherapy.

New concepts in phototherapy: photoisomerization of bilirubin IX alpha and potential toxic effects of light.

New information is summarized, indicating that configurational photoisomerization of bilirubin at the 5 and 15 carbon bridges is the major mechanism of bilirubin photocatabolism in vivo, and that singlet oxygen photooxidation plays only a minor role. The literature is reviewed concerning potentially damaging photodynamic reactions that are observed in vitro with vitamins, proteins, lipids, and nucleic acids, and their possible relationships to the limited number of toxic side-effects that have been detected with clinical phototherapy of neonatal jaundice. Secondary toxic effects, mediated by bilirubin photoderivatives or by retina-neuroendocrine pathways are also considered. Areas requiring further investigations are delineated.

Preparation and properties of bilirubin photoisomers.

Polar photoisomers of bilirubin were formed by irradiation of bilirubin in chloroform solution in the absence of O2. Two pairs of compounds were isolated with molecular weights identical with bilirubin. One pair reverted to bilirubin in polar media and gave chemical reactions similar to bilirubin; the other pair were not reconverted into bilirubin by chemical means and gave reactions distinct from those of bilirubin. However, both groups were reconverted into bilirubin by irradiation in chloroform solution in the absence of O2. The probable role of these photoisomers in the catabolism of bilirubin during phototherapy of neonatal jaundice is discussed.

Effects of phototherapy on hepatic function in human alcoholic cirrhosis.

Phototherapy has been used to treat neonatal jaundice, but little assessment has been made of possible beneficial effects on adult liver disease. Effects of phototherapy on bile acid turnover, biliary lipid concentration, liver function tests, and bromosulfophthalein (BSP) kinetics were studied in 8 alcoholic cirrhotics. Phototherapy initially increased biliary specific activity of both primary bile acids and then produced an acceleration of cholic and chenodeoxycholic acid decay curves. Pruritus was relieved in the 3 patients who had this symptom. The proposed mechanism for these changes is mobilization of bile acids from an expanded cutaneous bile acid pool with augmented bile acid excretion. No significant change in serum liver function tests or BSP plasma disappearance curves was seen. Phototherapy causes little improvement in intrinsic liver function, but produces specific changes in bile acid metabolism; these changes may be related to effects of light on a cutaneous bile acid pool.

Effect of phototherapy on bilirubin excretion in man and the rat.

Further evidence that the bilirubin excreted by Gunn rats during phototherapy is unconjugated is presented. The unconjugated bilirubin is not carried into bile as a water-soluble complex with rapidly excreted bilirubin derivatives, nor as a result of leakage of plasma protein into bile. Phototherapy does not augment biliary excretion of bilirubin in normal nonjaundiced rats, but does increase the concentration of conjugated bilirubin in the bile of patients with alcoholic cirrhosis, although their serum bilirubin concentrations are unaffected. The mechanism for augmented excretion of unconjugated bilirubin during phototherapy remains unexplained.

Photocatabolism of labeled bilirubin in the congenitally jaundiced (Gunn) rat.

To elucidate the mechanism by which phototherapy reduces serum bilirubin, studies were performed on the catabolism of labeled bilirubin in homozygous jaundiced Gunn rats before, during, and after a period of exposure to 1700 foot candles of daylight fluorescent light. Following equilibration with the body pool of an intravenously administered tracer dose of (3)H- or (14)C-bilirubin, radioactive and diazo reactive compounds were excreted in the bile at a slow, steady rate and plasma specific activity declined semilogarithmically. Subsequent exposure to light caused a marked increase in the biliary excretion of radioactive and diazoreactive compounds. Fecal and urinary radioactivity increased also but remained minor fractions of the total excreted radioactivity. After extinguishing the lights, these variables reverted gradually to control values. Spectral and chromotographic analysis of the excreted pigments and their azopigments demonstrated that the increased biliary radioactivity during phototherapy consisted of two roughly equal fractions: (a) unconjugated bilirubin, excreted at rates comparable to the output of conjugated bilirubin in the bile of normal nonjaundiced rats; and (b) water-soluble bilirubin derivatives, chromatographically identical with those found in Gunn rat bile under control lighting conditions but different from the products of photodecomposition of bilirubin in vitro. In some animals, phototherapy produced little decline in plasma bilirubin despite comparable acceleration of bilirubin catabolism. This was attributed tentatively to increased synthesis of early labeled bilirubin in these animals.