Choleretic effect of picroliv, the hepatoprotective principle of Picrorhiza kurroa

Picroliv, the hepatoprotective principle of the plant Picrorhiza kurroa, showed a dose-dependent (1.5-12 mg/kg x 7) choleretic effect in conscious rats and anaesthetised guinea pigs. It also possessed a marked anticholestatic effect against paracetamol- and ethynylestradiol-induced cholestasis. It antagonised the changes in bile volume as well as the contents (bile salts and bile acids). Silymarin, a known hepatoprotective agent, was tested simultaneously for comparison. Picroliv was found to be a more potent choleretic and anticholestatic agent than silymarin.     

Review article: mechanisms of action and therapeutic applications of ursodeoxycholic acid in chronic liver diseases

Ursodeoxycholic acid (ursodiol) is a non-toxic, hydrophilic bile acid used to treat predominantly cholestatic liver disorders. Better understanding of the cellular and molecular mechanisms of action of ursodeoxycholic acid has helped to elucidate its cytoprotective, anti-apoptotic, immunomodulatory and choleretic effects. Ursodeoxycholic acid prolongs survival in primary biliary cirrhosis and it improves biochemical parameters of cholestasis in various other cholestatic disorders including primary sclerosing cholangitis, intrahepatic cholestasis of pregnancy, cystic fibrosis and total parenteral nutrition-induced cholestasis. However, a positive effect on survival remains to be established in these diseases. Ursodeoxycholic acid is of unproven efficacy in non-cholestatic disorders such as acute rejection after liver transplantation, non-alcoholic steatohepatitis, alcoholic liver disease and chronic viral hepatitis. This review outlines the present knowledge of the modes of action of ursodeoxycholic acid, and presents data from clinical trials on its use in chronic liver diseases.     

Hepatoprotective effect of an active constituent isolated from the leaves of Ricinus communis Linn

Dose (1.5–12 mg/kg p.o. × 7) dependent choleretic, anticholestatic, and hepatoprotective activity in rat was observed with N-demethyl ricinine isolated from the leaves of Ricinus communis Linn. The anticholestatic and hepatoprotective activity was seen against paracetamol-induced hepatic damage. The choleretic and anticholestatic activity was evidenced by an increase in the volume of bile and its contents. The hepatoprotective effect was evaluated by an increase in the percent viability of hepatocytes (ex vivo) and by the reversal of altered enzymatic levels (glutamic oxaloacetic transaminase [GOT], glutamic pyruvic transaminase [GPT], and alkaline phosphatase) towards normal. The compound showed more potent activity than silymarin, a known hepatoprotective agent.     

Clinical efficacy and effectiveness of ursodeoxycholic acid in cholestatic liver diseases

Ursodeoxycholic acid (UDCA), previously used for cholesterol gallstone dissolution, is currently considered the first choice therapy for many forms of cholestatic syndromes. Many mechanisms and sites of action have been proposed for UDCA, but definitive data are still missing regarding the key points of its efficacy and optimal dosage in order to achieve a sustained clinical effect. Among the suggested mechanisms of action of UDCA, changes in bile acid pool composition, hepatocyte membrane protection, immunomodulatory effects and bicarbonate-rich hypercholeresis have been extensively studied. However, recent evidence indicate that UDCA is a potent intracellular signalling agent that counterbalances impaired biliary secretion, inhibits hepatocyte apoptosis and protects injured cholangiocytes against toxic effects of bile acids. It is clear that the relative contribution of these mechanisms to the anticholestatic action of UDCA depends on the type and stage of the liver injury. Available clinical evidence suggest that UDCA treatment has to be initiated as early as possible and that higher doses could be more efficacious in inducing and maintaining clinical remission of cholestatic diseases. The future availability of UDCA derivatives will possibly enhance the chances to effectively treat chronic cholestatic diseases.     

Hepatoprotective effect of picroliv against rifampicin-induced toxicity

Picroliv, the active constituent of the plant Picrorhiza Kurroa, showed significant hepatoprotective as well as anticholestatic activity against rifampicin-induced hepatic damage. Rifampicin (50 mg/kg ip × 6 days) resulted in the reduction of bile flow as well as its contents (bile salts and bile acids) in the conscious rat and anesthetized guinea pig. Further, it also caused a decrease in the viability and rate of oxygen consumption in isolated rat hepatocytes. Picroliv treatment significantly reversed the altered parameters of bile and hepatocytes. The hepatoprotective drug silymarin on comparison was found to be less active than picroliv. Drug Dev. Res. 40:299–303, 1997. © 1997 Wiley-Liss, Inc.     

水飞蓟素在慢性疾病中的抗氧化作用研究概述

水飞蓟素(silymarin)作为护肝药物被广泛应用于各类肝病,其护肝作用与水飞蓟素强大的抗氧化、抗炎和抗脂质沉积等作用有关。越来越多研究表明水飞蓟素在氧化应激引发的如心血管疾病、代谢综合征、神经退行性疾病、癌症和并发症等慢性疾病都具有良好治疗效果。本篇列举了近五年水飞蓟素治疗慢性病的通路研究,重点阐述慢性疾病与氧化应激的损伤机制和水飞蓟素的抗氧化能力在其中发挥的关键作用,以期为水飞蓟素的临床使用提供用药思路。     

The therapeutic effects of ursodeoxycholic acid as an anti-apoptotic agent

The dihydroxy bile acid, ursodeoxycholic acid (UDCA), has been in widespread clinical use in the Western world since the mid 1980s, when it was initially used for gallstone dissolution [1,2] and subsequently for the treatment of chronic cholestatic liver diseases [3,4]. Many clinical trials of UDCA in a variety of cholestatic disorders established biochemical and clinical improvements, and most importantly showed a significant prolongation of transplant-free survival after four years of treatment with UDCA in patients with primary biliary cirrhosis [5]. Despite its clinical efficacy, the precise mechanism(s) by which UDCA improves liver function during cholestasis is still a matter of debate [6]. It was initially considered that the choleretic effect of UDCA, coupled with its ability to cause a marked shift in the composition of the bile acid pool towards hydrophilicity, accounted for its mechanism of action. In recent years, however, it has become evident that UDCA and its conjugated derivatives are capable of exerting direct effects at the cellular, subcellular, and molecular levels by stabilising cell membranes, affecting signal transduction pathways, and regulating immune responses. In addition, we have shown that UDCA plays a unique role in modulating the apoptotic threshold in both hepatic and non-hepatic cells [7-10]. The purpose of this article is to examine the mechanism(s) by which UDCA prevents apoptotic cell death associated with cholestasis. In addition, we will also review a potentially novel and, heretofore, unrecognised role of UDCA as a therapeutic agent in the treatment of non-liver diseases associated with increased levels of apoptosis as a pathogenesis of the disorder.     

Pharmacogenetics of hepatocellular transporters

One of the main functions of the liver is the production of bile and the biliary secretion of endogenous and exogenous substances, including drugs and drug metabolites. Bile formation is a complex sequence of cellular events, which involves uptake of bile constituents and xenobiotics on the basolateral (sinusoidal) plasma membrane of hepatocytes and secretion of cholephilic compounds across the apical (canalicular) membrane. These uptake and efflux processes are maintained by distinct transport systems expressed at the two polar surface domains of liver cells. Any functional disturbance of these canalicular transport systems can lead to cholestatic liver disease, which is associated with intracellular accumulation of toxic bile constituents and consecutive cholestatic liver cell damage. Interaction of drugs with hepatobiliary transport systems is increasingly recognized as cause of acquired cholestatic syndromes. Thereby, genetically determined alterations of hepatobiliary transporter functions are important risk factors for an individual's susceptibility to develop cholestasis. Especially, mutations in canalicular transporter genes can cause certain forms of hereditary cholestatic liver disease, including progressive familial intrahepatic cholestasis or intrahepatic cholestasis of pregnancy. In addition, systematic genetic screenings have discovered numerous single nucleotide polymorphisms in hepatobiliary transporter genes that lead to amino acid exchanges in the encoded proteins. However, the functional consequences and the clinical relevance of most of these polymorphisms remain to be defined. This overview summarizes the physiological function of human hepatobiliary transport systems and discusses the impact of their genetic variations for the pathophysiology of cholestatic syndromes and the pharmacogenetics of drug-induced cholestasis.     

Prevention of taurolithocholate-induced hepatic bile canalicular distortions by HPLC-characterized extracts of artichoke (Cynara scolymus) leaves

The effects of water-soluble extracts of artichoke (Cynara scolymus L.) leaves on taurolithocholate-induced cholestatic bile canalicular membrane distortions were studied in primary cultured rat hepatocytes using electron microscopy. Artichoke extracts at concentrations between 0.08 and 0.5 mg/ml were able to prevent the formation of bizarre canalicular membrane transformations in a dose-dependent manner when added simultaneously with the bile acid. However, prevention also occurred when the hepatocytes were preincubated with the extracts, indicating that absorption of the bile acid to components of the extracts was not involved. These results demonstrate that artichoke leaf extracts exert a potent anticholestatic action at least in the case of taurolithocholate. This effect may contribute to the overall hepatoprotective influence of this herbal formulation.     

An updated review on drug-induced cholestasis: Mechanisms and investigation of physicochemical properties and pharmacokinetic parameters

Drug-induced cholestasis is an important form of acquired liver disease and is associated with significant morbidity and mortality. Bile acids are key signaling molecules, but they can exert toxic responses when they accumulate in hepatocytes. This review focuses on the physiological mechanisms of drug-induced cholestasis associated with altered bile acid homeostasis due to direct (e.g., bile acid transporter inhibition) or indirect (e.g., activation of nuclear receptors, altered function/expression of bile acid transporters) processes. Mechanistic information about the effects of a drug on bile acid homeostasis is important when evaluating the cholestatic potential of a compound, but experimental data often are not available. The relationship between physicochemical properties, pharmacokinetic parameters, and inhibition of the bile salt export pump among 77 cholestatic drugs with different pathophysiological mechanisms of cholestasis (i.e., impaired formation of bile vs. physical obstruction of bile flow) was investigated. The utility of in silico models to obtain mechanistic information about the impact of compounds on bile acid homeostasis to aid in predicting the cholestatic potential of drugs is highlighted. © 2013 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 102:3037–3057, 2013     

Treatment of cholestatic pruritus in children.

PURPOSE: The treatment of cholestatic pruritus in children is reviewed. SUMMARY: Cholestasis is characterized by an accumulation of substances that are normally secreted in the bile. Pruritus is a well-known feature of chronic cholestasis in both adults and children and has been reported as the most incapacitating symptom in children with chronic liver disease. Traditional agents, such as antihistamines, are typically ineffective as monotherapy in controlling cholestatic pruritus. As a result, clinicians have looked to other agents, such as rifampin, phenobarbital, ursodiol, opioid antagonists, and bile-binding resins, for attaining better control of pruritic symptoms. Each agent demonstrates different levels of efficacy in pediatric and adult literature. There are no guidelines or algorithms to guide therapy with these agents for children. As a result, an agent should be selected based on the patient's concurrent diseases and current medication regimen. Cholestyramine and ursodiol are both safe and inexpensive, with documented efficacy for cholestatic pruritus in children. Because cholestatic pruritus is likely a result of multiple mechanisms, combination therapy with agents that have differing mechanisms of action might be beneficial and could capitalize on potential synergy between the agents used. Future therapy for cholestatic pruritis may include serotonin antagonists, selective serotonin-reuptake inhibitors, and leukotriene antagonists. CONCLUSION: Depending on the underlying disease state resulting in cholestasis, phenobarbital, ursodiol, bile sequestering agents, and opioid antagonists appear to be most effective for treating pruritus related to intrahepatic cholestasis. Alternatively, rifampin appears to be the only agent with reported treatment efficacy for pruritus related to extrahepatic cholestasis.     

Protective effect of glycyrrhizin, glycyrrhetic acid and matrine on acute cholestasis induced by alpha-naphthyl isothiocyanate in rats

Alpha-naphthyl isothiocyanate (ANIT) is a known hepatotoxicant that causes acute cholestatic hepatitis characterized by the infiltration of neutrophils around bile ducts and necrotic hepatocytes. The effects of glycyrrhizin (GL), 18beta-glycyrrhetinic acid (GA), matrine (MT), oxymatrine (OMT), salvianolic acid B (SAB), silymarin (SI) and dexamethasone (DEX) on ANIT-induced acute cholestasis in rats were investigated. Serological and histological data demonstrated that the administration of GL, GA or MT all protected against hepatocyte injury and cholestasis induced by ANIT. Furthermore, the bile flow and the accumulative bile excretion of ketoprofen glucuronide (KPG), that were significantly suppressed by ANIT, were preserved in rats administered GL, GA or MT. DEX protected against acute cholestasis but did not protect against hepatocyte necrosis and elevated serum alanine aminotransferase levels following ANIT administration. Rats administrated OMT, SAB or SI were not resistant to ANIT toxicity. In summary, the protective effect of DEX is directed toward cholangiocytes rather than hepatocytes whereas the natural products, GA, GL and MT, exhibit significantly better protective effects against ANIT-induced liver damage including the protection of hepatocytes as well as cholangiocytes.     

水飞蓟素防治实验性肝病的作用及相关临床应用的研究进展

水飞蓟素是一种黄酮类化合物，具有清除活性氧、抗脂质过氧化、抗炎、抗肿瘤等多种药理作用。笔者通过查阅大量相关文献，发现水飞蓟素对各种肝病均具有较好的防治作用。随着基础研究的深入，发现水飞蓟素还可以促进肝细胞的修复与再生，与抗病毒药物及其他护肝药物联用时能更显著地降低血清转氨酶水平及改善肝纤维化，具有安全性高及耐受性好的优点。本文主要对水飞蓟素对不同肝病的防治作用、作用机制及其临床应用现状进行综述，以期为水飞蓟素在防治肝病方面的深入研究、药物开发和临床应用等方面提供参考。     

Hepatocyte-based in vitro model for assessment of drug-induced cholestasis

Early detection of drug-induced cholestasis remains a challenge during drug development. We have developed and validated a biorelevant sandwich-cultured hepatocytes- (SCH) based model that can identify compounds causing cholestasis by altering bile acid disposition. Human and rat SCH were exposed (24–48 h) to known cholestatic and/or hepatotoxic compounds, in the presence or in the absence of a concentrated mixture of bile acids (BAs). Urea assay was used to assess (compromised) hepatocyte functionality at the end of the incubations. The cholestatic potential of the compounds was expressed by calculating a drug-induced cholestasis index (DICI), reflecting the relative residual urea formation by hepatocytes co-incubated with BAs and test compound as compared to hepatocytes treated with test compound alone. Compounds with clinical reports of cholestasis, including cyclosporin A, troglitazone, chlorpromazine, bosentan, ticlopidine, ritonavir, and midecamycin showed enhanced toxicity in the presence of BAs (DICI ≤ 0.8) for at least one of the tested concentrations. In contrast, the in vitro toxicity of compounds causing hepatotoxicity by other mechanisms (including diclofenac, valproic acid, amiodarone and acetaminophen), remained unchanged in the presence of BAs. A safety margin (SM) for drug-induced cholestasis was calculated as the ratio of lowest in vitro concentration for which was DICI ≤ 0.8, to the reported mean peak therapeutic plasma concentration. SM values obtained in human SCH correlated well with reported % incidence of clinical drug-induced cholestasis, while no correlation was observed in rat SCH. This in vitro model enables early identification of drug candidates causing cholestasis by disturbed BA handling.     

Altered pharmacokinetics and hepatic uptake of TBuMA in ethynylestradio-induced cholestasis

The objective of this study was to examine the pharmacokinetics of organic cations in intrahepatic cholestatic rats. A pretreatment with 17alpha-ethynylestradiol was used to induce intrahepatic cholestasis, and tributylmethylammonium (TBuMA) was used as a representative model organic cation. When [3H]TBuMA was intravenously administered1 the AUC value for TBuMA was significantly increased by 79% in cholestasis, and its total systemic clearance was consequently decreased by 46%. In addition, the in vivo hepatic uptake clearance of TBuMA from the plasma to the liver was decreased by 50% in cholestasis. The concentration of bile salts in plasma was increased by 2.1 fold in cholestatic rats. Since TBuMA forms ion-pair complexes with anionic components such as bile salts, the decreased hepatic uptake of TBuMA in cholestasis may be due to a change in endogenous components, e.g., bile salts in the plasma. In isolated normal hepatocytes, the uptake clearance for TBuMA in the presence of cholestatic plasma was decreased by 20% compared with normal plasma. Therefore, we conclude that the inhibition of the hepatic uptake process by the cholestasis may be in part due to the increased formation of ion-pair complexes of TBuMA with bile salts in the plasma.     

Protective effect of Jasonia montana against ethinylestradiol-induced cholestasis in rats

Estrogens, and particularly glucuronides such as ethinylestradiol (EE), have been shown to cause cholestasis in animal studies, by reducing bile acid uptake by hepatocytes. The aim of the present article is to investigate anticholestatic activity of the ethanolic extract of the aerial parts of Jasonia montana against liver cholestasis induced by EE in adult female rats in an attempt to understand its mechanism of action, which may pave the way for possible therapeutic applications. Subcutaneous administration of 100 μg/kg b.w. ethinylestradiol to rats induced hepatocellular cholestasis with a significant decrease in serum cholesterol, bile acids and bilirubin levels as well as in hepatic superoxide dismutase (SOD), glutathione peroxidase (GPx), glutathione reductase (GR) activities and hepatic total, protein-bound and non-protein sulfhydryl groups. Also, treatment with EE produced significant increase in serum Pi-glutathione-s-transferase (Pi-GST), gamma glutamyl transpeptidase (γ-GT) and alpha-glutathione-s-transferase (α-GST) activities as well as serum nitric oxide (NO) and tumor necrosis factor alpha (TNF-α) level and hepatic malondialdehyde (MDA) level as compare to control group. Oral administration of the aerial parts of ethanolic extract at a concentration of 150 mg/kg b.w. daily to rats treated with EE for 15 days showed a significant protection against-induced decrease in serum cholesterol, bile acids and bilirubin levels. The treatment also resulted in a significant increase in hepatic SOD, GPx and GR activities as well as hepatic total, protein-bound and non-protein sulfhydryl groups. In addition, the extract could inhibit serum Pi-GST, γ-GT and α-GST activities as well as reduce serum TNF-α, NO and hepatic MDA as compare to ethinylestradiol treated rats. High content of flavonoids and phenolic compounds was found in ethanolic extract, which may be responsible for free radical activity. The results clearly suggest that the aerial parts of J. montana extract may effectively normalize the impaired antioxidant status in ethinylestradiol (EE)-cholestatic model. Thus the extract may have a therapeutic value in drug-induced biliary cholestasis as well as in hormonal therapy.     

Farnesoid X receptor modulators (2011 – 2014): a patent review

Introduction: Farnesoid-X-receptor (FXR) is the receptor for primary bile acids expressed in enterohepatic tissues where it regulates bile acid uptake, metabolism and disposal. For its role as a bile acid sensor, FXR has been thought to be an important target in the treatment of cholestatic disorders, a family of diseases in which endogenous bile acids accumulate in the body. Cholestasis might occur as a consequence of inborn metabolic errors and three major disorders, intra-hepatic cholestasis in pregnancy, primary biliary cirrhosis (PBC) and primary sclerosing cholangitis account for the vast majority of clinical cholestasis occurring in adulthood. In addition, FXR agonists are gaining attention as potential regulators of lipid and glucose metabolism and therefore as new therapeutical approaches to the treatment of fatty liver disease, type 2 diabetes and obesity.

Areas covered: New chemical entities as FXR modulators and their in vitro and in vivo efficacy are reviewed with particular focus on patents and peer-reviewed publications in the period 2011 – 2014.

Expert opinion: FXR agonists have shown robust therapeutic potential and results from clinical trials have supported their use in the treatment of liver disorders including PBC and fatty liver disease despite side effects.     

Beneficial drugs for liver diseases

Liver diseases are a major problem of worldwide proportions. However, the number of drugs actually used successfully in humans is very small. In this review some of the most promising/studied drugs utilized for liver diseases were chosen and analysed critically from the basic to the clinical point of view. Antiviral agents are not discussed because excellent reviews have appeared on this topic. The compounds/preparations described herein are, alphabetically: colchicine, corticosteroids, curcumin, glycyrrhizin, interferons (for their antifibrotic properties), Liv 52, nitric oxide, resveratrol, silymarin, sulfoadenosylmethionine, and thalidomide. Colchicine and corticosteroids have been studied extensively in animals and humans; most clinical studies suggest that these compounds are not useful in the treatment of liver diseases. Glycyrrhizin is an herbal medicine with several components that has interesting hepatoprotective properties in patients with subacute liver failure but deserves more prospective controlled trials. Interferon has shown interesting antifibrotic properties in animals and humans; prospective studies on their antifibrotic/fibrolytic activity are required. Curcumin, resveratrol and thalidomide are very attractive newly discovered protective and curative compounds on experimental hepatic diseases. Their mechanism of action is associated with the ability to down-regulate NF-kappaB and to decrease pronecrotic and profibrotic cytokines. Unfortunately, clinical studies are lacking. Sulfoadenosylmethionine and silymarin are also promising drugs utilized mainly in cholestasis but the benefits can be expanded if more controlled trials are performed. The future is to carry out controlled prospective double-blind multicenter studies with the newly discovered drugs with proven beneficial effects on animals. Fundamental hepatobiology should also be encouraged.