Hepatology, February 1999, p. 585-589, Vol. 29, No. 2

Hepatitis C Virus RNA Profiles in Chronically Infected Individuals: Do They Relate to Disease Activity?

Patrizia Pontisso¹, Giorgio Bellati², Maurizia Brunetto², Liliana Chemello¹, Guido Colloredo², Rosellina Di Stefano³, Massimo Nicoletti¹, Maria Grazia Rumi⁴, Maria Grazia Ruvoletto¹, Roberta Soffredini⁴, Lilli Mario Valenza³, and Giuseppe Colucci⁵

From the ¹Department of Clinical and Experimental Medicine, University of Padova, Italy; ²Division of Gastroenterology, Molinette Hospital, Torino, Italy;³Institute of Internal Medicine, University of Palermo, Italy; ⁴Department of Internal Medicine, University of Milano, Italy; and ⁵Roche Molecular Systems, Basel, Switzerland.

ABSTRACT

Fluctuations of Hepatitis C virus (HCV)-RNA serum levels were monitored in a multicenter study in 76 chronic HCV carriers who had been followed longitudinally without receiving antiviral therapy to assess their relation with the course of liver disease activity. Forty-four patients had normal transaminases over more than 2 years, while 32 additional patients had fluctuating levels.Viral load was measured in serial serum samples prospectivelycollected for 10 to 12 months in 54 patients and in sera stored yearly up to 8 years in an additional 22 patients. In patients tested monthly, a lesser extent of fluctuations was detected in cases with constantly normal transaminases as compared with those with fluctuating transaminases. In the former group, the mean difference between maximum and minimum values observed in each individual patient was 0.7 Log, while in the latter group, it was 1.3 Log (P = .0004). Most of these patients experienced, on average, three peaks of viremia over 1 year. The range of variation observed upon yearly testing was between 0.2 and 2.2 Log and did not reach statistical significance between the two groups. Inconclusion, a careful viral replication profile can be achievedonly by monthly testing, because longer time intervals could missviremia fluctuations. HCV-RNA levels are more stable in asymptomaticHCV carriers than in patients with biochemical activity of liverdisease. (HEPATOLOGY 1999;29:585-589.)

INTRODUCTION

Chronic infection with Hepatitis C virus (HCV) is characterized by persistent viremia. HCV RNA is usually detected in serum by sensitive polymerase chain reaction (PCR)-based techniques and has become a useful tool for diagnosis and monitoring. Besides methods for qualitative detection of viremia, a number of procedures to quantify serum HCV RNA have been developed, including end-point dilution PCR,¹ competitive PCR,^2,3 isothermal nucleic acid amplification,⁴and signal-amplification branched DNA.⁵ Routine use of these techniques in a wide clinical setting is hampered by problems of specificity and sensitivity, lack of reproducibility, poor standardization, and high cost.⁶ Recently, methods forquantitative assessment of HCV-RNA levels have become commerciallyavailable and are being extensively evaluated in clinical studies,particularly in patients treated with interferons and antivirals.⁷ Little is known about viral kinetics in untreated patients, because most evaluations of the level of viremia are based on single determinations. If wide spontaneous fluctuations occur, they could mimic treatment-inducedeffects or lead to under- or overestimate baseline values. Ina few published studies, different time intervals have been evaluated and discordant conclusions have been reported. Either trivial or consistent differences of viral load over time have been described after observation periods ranging from days to months.^8-12 To assess the spontaneous behavior of serum HCV-RNA levels over a reasonable length of time upon close observation, we monitored chronic HCV carriers who had been followed longitudinally without receiving any antiviral therapy and then analyzed their patterns of virus replication in relation to biochemical and histological activity of liverdisease.

PATIENTS AND METHODS

Patients. Seventy-six chronic carriers of HCV were evaluated in a multicenter study (the HEPCCOM Italian Study) in which collection and virological analysis were performed by each participating Center, including the Division of Gastroenterology, Molinette Hospital-Torino, the Department of Internal Medicine-University of Milano, the Department of Clinical and Experimental Medicine-University of Padova, and the Institute of Internal Medicine-University of Palermo. The study population included 44 patients with constantly normal alanine aminotransferase (ALT) values since at least 6  months before enrollment in the study and during a follow-up period lasting for more than 2 years (mean follow-up, 3 years; range,2-8 years), and 32 additional patients with fluctuating ALT. There were 42 males and 34 females, with a median age of 53 years (range, 20-68 years). All were HCV-RNA-positive by qualitative PCR before entering the study. None of the patients had evidence of ongoing Hepatitis B virus or human immunodeficiency virus infection; current alcohol and/or drug abuse or metabolic disorders were also excluded in all patients. None of the patients underwent antiviral treatment during the time of the study. Serial serum samples collected yearly over a period of several years were available for 22 patients (median samples/patient, 4 samples; range, 3-8 samples/patient). In 54 additional cases, monthly serum and plasma samples wereobtained during a prospective follow-up period, lasting 10 ± 2  months (mean ± SD). All samples were collected in sterile conditions, centrifuged, and stored in 500-µL aliquots at -80°C within 3 hoursafter withdrawal. Only unthawed samples were used for HCV-RNAmeasurements. In 49 patients, liver biopsy was obtained just before or during the time of the study and was consistent with minimal liver lesions in 3 patients, mild chronic hepatitis in 25 patients, moderate chronic hepatitis in 20 patients, and severe hepatitis in 1  patient.

Viral Markers. Anti-HCV was determined by commercially available second-generation enzyme-linked immunosorbent assay kits (Ortho Diagnostics, Raritan, NJ) and confirmed by radioimmunoblot assay 2 or 3. Hepatitis B surface antigen and anti-human immunodeficiency virus were detected by enzyme-linked immunosorbent assay (Abbott Diagnostics, North Chicago, IL).

Qualitative HCV-RNA Determination. To assess HCV RNA in serum, either the commercially available qualitative Amplicor HCV assay (Roche Molecular Systems, Branchburg, NJ) or home-made reverse-transcription nested PCR were performed. The former assay showed sensitivity and specificity similar to in-house reverse-transcription PCR in a large confirmatory study¹³ to a cut-off level of 10³ genomes/mL.

HCV Genotype Determination. The HCV genotype was determined by InnoLipa assay (Innogenetics, Gent, Belgium) or by a previously published protocol¹⁴ that has been validated by direct sequencing and by InnoLipa assay.¹⁵ Briefly, PCR-amplified products were spotted in parallel on nylon filters and hybridized with type-specific probes derived form the 5’noncoding region, labeled with deoxyuridine triphosphate fluoresceine, the reaction being revealed by an enhanced chemiluminescence method (ECL, Amersham International plc, UK) on autoradiographic films.

Quantitation of HCV RNA. Viral load was measured using a recently developed PCR system that includes a quantitation standard that is coamplified with the target HCV RNA (Amplicor HCV Monitor, Roche Molecular Systems).¹⁶ RNA was extracted from 100 µL of serum and from the standard containing a known number of RNA copies by a guanidium-thiocyanate method and precipitated by isopropanol. Single-tube reverse transcription and 5′ untranslated region genomic amplification was then performed in a 9600 thermal cycler (Perkin Elmer, Norwalk, CT) using rTthDNA polymerase in which AmpErase enzyme had been introduced toavoid carry-over. Amplified products were immediately denaturedand transferred to probe-coated microwell plates after serialfivefold dilution. Parallel HCV-specific and quantitation standard-specific hybridization was revealed by enzymatic detection and optical density measurement at a wavelength of 450 nm. The concentration of native HCV RNA was automatically calculated and was based on the ratio between the native bound HCV-RNA signal and the bound internal quantitation-standard signal.

Laboratory standardization of the assay included the following evaluations: 1) sera from 4 patients (2 with high viremia and2 with low viremia) run in decuplicate to assess the intra-assay variation; and 2) in 10 patients, HCV-RNA levels were evaluated using both serum and plasma samples obtained monthly, to assess variations of HCV-RNA determination efficiency when using sera.¹⁷

Statistical Analysis. The Kruskal-Wallis ANOVA median test, Spearman correlation, <="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/chi.gif" alt="X" width="9" height="10" />² and the Fisher’s exact test were used for analysis of the results. Statistical calculations were performed using the program STATISTICA (Statsoft, Inc., Tulsa, OK). HCV-RNA levels were expressed as Log-transformed values to reduce the interference of extreme values.

RESULTS

Serum HCV-RNA Levels

Laboratory Standardization. Using a standard panel of sera at a known HCV-RNA concentration, provided by Roche Molecular Systems, the sensitivity of the assay was estimated between 10³ and 10⁴ genomes/mL.

The reproducibility experiments of the HCV quantitation assay showed an intra-assay coefficient of variation ranging from 57% to 23% when sera below or above 10⁴ were used, respectively. Using logarithmic transformation of the results, the standard deviation of HCV-RNA determinations per subject (one serum run in decuplicate) ranged from 0.14 to 0.17. Therefore, in agreement with previously published results,¹⁶ changes beyond 0.5 Log were considered as true fluctuations and not as intrinsic test variations.

A good correlation was observed when viral load was assessed using serum or plasma samples, obtained from the same blood withdrawal and run at the same time (Spearman correlation r = .82). These results are in keeping with previous findings,^16,18 while they do not confirm other data obtained with a competitive, home-made quantitative test,¹⁷ underlying the fact that different technical approaches can influence final results.

Viremia Profiles. Of the 76 HCV-infected patients, 44 had constantly normal ALT during follow-up, while 32 had fluctuating abnormal ALT. Liver biopsies were obtained from 23 patients with a normal transaminase profile and in 26 patients with elevated ALT. table 1 shows thehistological distribution in relation to transaminase and virological profiles. A significantly higher proportion of patients with a normal transaminase profile had minimal liver lesions or mild chronic hepatitis, as compared with patients with fluctuating ALT, who showed more active histology. The rate of fluctuations beyond the variability of the assay was similar in patients with mild or moderate chronic hepatitis. All 3 patients with minimal changes showed stable viremic levels over time.

View This table

table 1. Histological Features Observed in Chronic HCV Patients in Relation to Transaminase Profile  and Viremia Levels

Relation to HCV Genotype. Overall, 38 patients were infected with genotype 1, 14 were infected with genotype 2, and 2 patients were infected with genotype3. HCV carriers infected with genotype 1 showed higher levels of viremia than those infected with genotype 2 or genotype 3 (P  < .001), as shown in table 2. The observed differences are likely the result of the underestimation of HCV-RNA load in viral types 2 and 3 by the version of the assay used.^6,18

View This table

table 2. Viral Load in Relation to Infecting Genotype

Viral Fluctuations Over Time in Relation to Clinical Profile. Serial determinations of viral load were performed in 22 patients with yearly collected serum samples (10 with normal ALT and 12 with elevated ALT), while for 54 additional patients (28  with normal ALT and 26 with elevated ALT), monthly collected serum samples were studied. table 3 shows individual changes of viremia, expressed as the maximum Log difference detected during the observationperiod, in relation to transaminase profile, infecting genotype,and histological findings. A significant difference was identifiedin monthly tested samples between patients with a normal ALT profilecompared with patients with elevated ALT. Infecting genotype andoverall histology did not show any influence on viremia profiles,although all the patients with minimal lesions had low fluctuationsof HCV RNA, but their small number did not allow any definitiveconclusion.

View This table

table 3.   Maximum Changes of HCV RNA (Log genomes/mL) Observed in Serum During Follow-up in HCV-Infected Patients

The variability of HCV-RNA values in serial measurements of each patient over time is reported in Fig. 1. In patients withnormal ALT, monthly testing showed changes <1 Log in the majorityof the patients, 23% of them being below the intrinsic variabilityof the assay, while larger changes were observed in patients withfluctuating ALT. These features were not detectable in patientstested yearly, likely because long-term viral kinetics revealedthat in all the patients examined monthly, a maximum of threepeaks of viremia, defined as >50% increase, were experienced over1 year. This occurred in 59% of the patients, while 33% experienced two HCV-RNA peaks, and only 8% had none or one peak. The high likelihood of testing inter-spikes levels of HCV RNA when comparing single points per each year most likely explains this finding.

<="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/hepa47637001.gif" alt="" width="200" height="94" /> View Larger Version

Fig. 1.   Distribution of the difference between the maximum and minimum value       (<="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/Delta.gif" alt="" width="11" height="10" />) of HCV RNA in samples tested over time in individual patients. The median value for each group is represented by a solid bar. The gray zone indicates the range of intrinsic assay variability.

Temporal behavior of viremia in relation to ALT profile is described in Fig. 2. HCV-RNA fluctuations above the assay variabilitywere observed in 77% of the patients with normal ALT profile andin 92% of the patients with abnormal ALT. In this latter group,viral profile was synchronous with transaminase behavior in 38%of the patients, while in 62% of them, the two parameters werenot synchronized (Fig. 3C and 3D).

<="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/hepa47637002.gif" alt="" width="200" height="155" /> View Larger Version

Fig. 2.   Median values of biochemical profiles in relation to HCV-RNA levels over time observed in patients studied monthly with a normal (A) and abnormal (B) ALT profile.

<="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/hepa47637003.gif" alt="" width="200" height="124" /> View Larger Version

Fig. 3.   Examples of ALT and HCV-RNA behavior in individual patients with constantly normal ALT (A, B) and in patients with fluctuating ALT (C, D), prospectively studied monthly for 12 months.

DISCUSSION

Fluctuations over time of HCV replication during the course of chronic HCV infection is a relevant issue that has not been definitely explored. Several clinical relations with replication activity of the virus, including grade of disease and response to antiviral drugs, have been based on single-time-point determinations of viremia.^10,19-28 To date, conflicting results have been reported on long-term monitoring of viral replication. Different time intervals, ranging from diurnal to monthly determinations, have been evaluated using different methods of measurement, and discordant conclusions might result from the above-mentioned variables. No fluctuations were reported when daily to monthly analysis over 3 months wasperformed using the branched-DNA assay,¹¹ while wide monthlyfluctuations have been described over 6 months using a competitive reverse-transcription PCR technique.⁸ In this multicenter study,viremia has been monitored in a large number of untreated patientsboth on a monthly and a yearly basis, and the majority of thesamples has been prospectively collected, following standard criteria of specimen handling and storage conditions. Monthly measurement of HCV RNA revealed that the majority of the patients experienced, on average, three peaks of viremia over 1 year, with a median change of absolute value of about 1 Log, while the remaining patients had a lower frequency of HCV-RNA flares. These findings indicate that a careful viral replication profile can be obtained only by monthly testing, because longer time intervals could miss viremia fluctuations. Monthly variations of HCV RNA were significantly lower in patients with a normal transaminase profile, as compared with those with abnormal ALT, suggesting a relationship between the two parameters. Comparison of ALT and HCV-RNA patterns in patients with fluctuating ALT revealed that in the majority of the patients, fluctuations were asynchronous (i.e., two ALT flares and three HCV-RNA peaks per year). While no impairment of HCV replication seems to occur in patients with normal transaminases, hepatocyte lysis observed in patients with fluctuating ALT could hamper viral replicative activity. As a consequence, a single determination of HCV-RNA level in patients with abnormal ALT does not seem adequate to classify individual patients as “high or low” viremic. It has been repeatedly reported that low viral loads are associated with better response to interferon, either alone or in combination with ribavirin.^25-27,29 As a result of the observed viral fluctuations, the suggestion of waiting to start treatment until the patients have lower viremia to increase the response rates could arise. However, prospective trials are needed to specifically address this point. Liver histology did not show any significant correlation with replication activity of the virus, but in the study population, extreme histological features, including minimal changes and active cirrhosis, were not adequately represented. Further studies are required to draw conclusions on the relationship between viral replication profile and liver disease activity at the histological level.

When patients were divided according to the infecting genotype, similar fluctuations were detected in all groups, although absolute values of viremia observed in cases infected with genotype 1 were higher than those detected in patients infected with genotype2 and with genotype 3. This is likely a result of a better efficiency of detection of genotype 1 by the current version of the assay.^6,18

In conclusion, long-term monitoring of viral replication showed that HCV RNA is relatively stable over time in asymptomatic HCV carriers, while a low number of viremic flares can occur over a year in patients with biochemical activity of liver disease.

Acknowledgment

The authors are deeply greateful to Professors A. Alberti, F. Bonino, M. Colombo, and A. Craxì for their substantial contribution in the design of the study and in the discussion of the results.

Abbreviations

Abbreviations: HCV, Hepatitis C virus; PCR, polymerase chain reaction; ALT, alanine aminotransferase.

Footnotes

Received June 12, 1998; accepted October 2, 1998.

Address reprint requests to: Patrizia Pontisso, M.D., Dipartimento di Medicina Clinica e Sperimentale-Clinica Medica 5°, Università di Padova, Via Giustiniani, 2 35128 Padova, Italy. E-mail: patrizia@ux1.unipd.it; fax: 49-8754179.

REFERENCES

1.	Simmonds P, Zhang LQ, Watson HG, Rebus S, Ferguson ED, Balfe P, Leadbetter GH, et al. Hepatitis C quantification and sequencing in blood products, haemophiliacs, and drug users. Lancet 1990;336:1469-1472
2.	Kaneko S, Murakami S, Unoira M, Kobayashi K. Quantitation of Hepatitis C virus RNA by competitive polymerase chain reaction. J Med Virol 1992;37:278-282.
3.	Young KK, Archer JJ, Yokosuka O, Omata M, Resnick RM. Detection of Hepatitis C virus RNA by a combined reverse transcription PCR assay: comparison with nested amplification and antibody testing. J Clin Microbiol 1995;33:654-657
4.	Kievitis T, van Gemen B, van Strijp D, Schukkink R, Dircks M, Adrianse H, Malek L, et al. NASBA isothermal enzymatic in vitro nucleic acid amplification optimized for the diagnosis of HIV-1 infection. J Virol Methods 1991;35:273-286.
5.	Urdea MS, Horn T, Fultz TJ, Anderson M, Running JA, Hamren S, Ahle D, et al. Branched DNA amplification multimers for the sensitive, direct detection of human hepatitis viruses. Nucleic Acids Symp Ser 1991;24:197-200
6.	Ohno T, Lau JYN. The “Gold Standard” accuracy, and the current concepts: Hepatitis C virus genotypes and viremia. HEPATOLOGY 1996;24:1312-1315
7.	Gretch DR, dela Rosa C, Carithers RL, Willson RA, Williams B, Corey L. Assessment of Hepatitis C viremia using molecular amplification technologies: correlation and clinical implications. Ann Intern Med 1995;123:321-329
8.	Giostra F, Francesconi R, Groff P, Manzin A, Solforosi L, Lari F, Ballardini G, et al. Wide fluctuation of plasmatic HCV genome levels in serial samples of patients before interferon (IFN) treatment [Abstract]. HEPATOLOGY1995;22:341A
9.	Gordon SC, Khan BA, Dmuchowski CF, Kodali VP, Silverman AL. The spontaneous fluctuation of viremia over time in untreated patients with chronic type C hepatitis [Abstract]. HEPATOLOGY 1995;22:341A.
10.	Zeuzem S, Franke A, Lee JH, Herrmann G, Ruster B, Roth WK. Phylogenetic analysis of Hepatitis C virus isolates and their correlation to viraemia, liver function tests and histology. HEPATOLOGY 1996;24:1003-1007
11.	Nguyen TT, Sedghi-Vaziri A, Wilkers LB, Mondala T, Pockros PJ, Lindsay KL, McHutchison JG. Fluctuations in viral load (HCV RNA) are relatively insignificant in untreated patients with chronic HCV infection. J Viral Hepat 1996;3:75-78.
12.	Hollingsworth RC, Sillekens P, van Deursen P, Neal KR, Irving WL, the Trent HCV Study Group. Serum HCV RNA levels assessed by quantitative NASBA: stability of viral load over time, and lack of correlation with liver disease. J Hepatol 1996;25:301-306
13.	Gerken G. Pontisso P, Roggendorf M, Rumi MG, Simmonds P, Trepo C, Zeuzem S, et al. Clinical evaluation of a single reaction, diagnostic PCR assay for the detection of Hepatitis C virus (HCV) RNA. J Hepatol 1996;24:33-37
14.	Pontisso P, Ruvoletto MG, Nicoletti M, Tisminetzky S, Gerotto M, Levrero M, Artini M, et al. Distribution of three major Hepatitis C virus genotypes in Italy. A multicenter study of 495 patients with chronic Hepatitis C. J Viral Hepat 1995;2:33-38
15.	Pontisso P, Gerotto M, Ruvoletto MG, Fattovich G, Chemello L, Tisminetzky S, Baralle F, et al. Hepatitis C genotypes in patients with dual Hepatitis B and C virus infection. J Med Virol 1996;48:157-160
16.	Miskovsky EP, Carrella AV, Gutekunst K, Sun C-A, Quinn TC, Thomas DL. Clinical characterization of a competitive PCR assay for quantitative testing of Hepatitis C virus. J Clin Microbiol 1996;34:1975-1979
17.	Manzin A, Bagnarelli P, Menzo S, Giostra F, Brugia M, Francesconi R, Bianchi FB, et al. Quantitation of Hepatitis C virus genome molecules in plasma samples. J Clin Microbiol 1994;32:1933-1944
18.	Hawkins A, Davidson F, Simmonds P. Comparison of plasma virus load among individuals infected with Hepatitis C virus (HCV) genotypes 1,2, and 3 by Quantiplex HCV RNA assay version 1 and 2, Roche Monitor Assay, and an in-house limiting dilution method. J Clin Microbiol 1997;35:187-192
19.	Busch MP, Wilber JC, Johnson P, Tobler L, Evans CS. Impact of specimen handling and storage on detection of Hepatitis C virus RNA. Transfusion 1995;32:420-425
20.	Hagiwara H, Hayashi N, Mita E, Naito M, Kasahara A, Fusamoto H, Kamada T. Quantitation of Hepatitis C virus RNA in serum of asymptomatic blood donors and patients with type C chronic liver disease. HEPATOLOGY1993;17:545-550
21.	Lau JY, Davis GL, Kniffen J, Qian KP, Urdea MS, Chan CS, Mizokami M, et al. Significance of serum Hepatitis C virus RNA levels in chronic Hepatitis C. Lancet 1993;341:1501-1504
22.	Gretch D, Corey L, Wilson J, dela Rosa C, Willson R, Carithers Jr R, Busch M, et al. Assessment of Hepatitis C virus RNA levels by quantitative competitive RNA polymerase chain reaction: high titer viremia correlates with advanced stage of disease. J Infect Dis 1994;169:1219-1225
23.	Naito M, Hayashi N, Hagiwara H, Hiramatsu N, Kasahara A, Fusamoto H, Kamada T. Serum Hepatitis C virus RNA quantity and histological features of Hepatitis C virus carriers with persistently normal ALT levels. In: HEPATOLOGY, 1994:1971-875.
24.	Martinot-Peignoux M, Marcellin P, Gournay J, Gabriel F, Courtois F, Branger M, Wild AM, et al. Detection and quantitation of serum HCV-RNA by branched DNA amplification in anti-HCV positive blood donors. J Hepatol 1994;20:676-678
25.	Yamada GR, Takatani F, Kishi M, Takahashi M, Doi T, Tsuji T, Shin S, et al. Efficacy of interferon alfa therapy in chronic Hepatitis C depends primarily on Hepatitis C virus RNA level. HEPATOLOGY 1995;22:1351-1354
26.	Martinot-Peignoux M, Marcellin P, Pouteau M, Castelnau C, Boyer N, Poliquin M, Degott C, et al. Pretreatment serum Hepatitis C virus RNA levels and Hepatitis C virus genotype are the main and independent prognostic factors of sustained response to interferon alfa therapy in chronic Hepatitis C. HEPATOLOGY 1995;22:1050-1056
27.	Magrin S, Craxì A, Fabiano C, Marino L, Fiorentino G, Lo Iacono O, Volpes R, et al. HCV vireamia is more important than genotype as predictor of response to interferon in Sicily (Southern Italy). J Hepatol 1996;25:583-590
28.	Smith DB, Davidson F, Yap PL, Brown H, Kolberg J, Detmer J, Urdea M, et al. Levels of Hepatitis C virus in blood donors infected with different viral genotypes. J Infect Dis 1996;173:727-30
29.	Reichard O, Norkrans G, Frydén A, Braconier JH, Sonnerborg A, Weiland O, for the Swedish Study Group. Randomised, double-blind, placebo-controlled trial of interferon <="https://www.hepatitiscentral.com/images/hcv/hepatitis/virus/alpha.gif" alt="alpha" width="8" height="7" />-2b with and without ribavirin for chronic Hepatitis C. Lancet 1998;351:83-87

 

Copyright © 1999 by the American Association for the Study of Liver Diseases.