临床诊断为非甲～戊型肝炎患者的病原学研究

目的探讨临床诊断为非甲-戊型肝炎患者的病原学。方法 采用巢式PCR（nPCR)检测HBV、TTV、B19、和SENV DNA；用逆转录巢式PCR（RT-nPCR)检测HGV和HCV RNA。结果 60例临床诊断为非甲-戊型肝炎患者中，单独HBVDNA阳性30例（阳性率为50.0%)，HBV和TTVDNA阳性10例（16.7%)，HBV和B19DNA阳性6例（10.0%)，HCVRNA、HBV和SENVDNA阳性1例（1.7%)，单独HCVRNA阳性1例（1.7%)，HCVRNA和B19DNA阳性1例（1.7%),HGVRNA无一例阳性，单独B19DNA阳性2例（3.3%)。单独TTVDNA阳性1例（1.7%)，另8例（13.3%)上述病毒核酸均为阴性。HBV合并感染TTV或B19对其血清学生化指标无影响。结论HBV是临床诊断为非甲-戊型肝炎的主要病原，HGV、TTV、B19和SENV与非甲-戊型肝炎无关。     

Prevalence of hepatitis B, hepatitis C, GB virus C/hepatitis G and TT viruses in predialysis and hemodialysis patients

Patients with chronic renal failure on hemodialysis have a high risk of infections with viruses such as hepatitis B (HBV), hepatitis C (HCV), GB virus C/hepatitis G (GBV-C/HGV) and TT (TTV) viruses. The prevalence of HBV, HCV, GBV-C/HGV and TTV in patients with chronic renal failure who are on conservative management before entering into a hemodialysis program (predialysis) in comparison with hemodialyzed patients was studied to elucidate whether the high prevalence of these viruses is influenced by that observed in the predialysis stage. The presence of hepatitis B virus surface antigen (HBsAg), HCV RNA, GBV-C/HGV RNA and TTV DNA was analyzed in sera from 80 patients with chronic renal failure (35 on predialysis and 45 on hemodialysis). HBsAg, HCV RNA, GBV-C/HGV RNA and TTV DNA were detected in one (2.8%), six (17.1%), eight (22.5%) and 16 (45.7%) of the 35 patients on predialysis. Two (5.7%) of these patients were coinfected with HCV and GBV-C/HGV, whereas six (17.1%) had GBV-C/HGV and TTV coinfection. In the 45 hemodialyzed patients, HBsAg, HCV RNA, GBV-C/HGV RNA and TTV DNA were detected in one (2.2%), two (4.4%), seven (15.5%) and 26 (57.7%). One (2.2%) patient had HBV and TTV coinfection, two (4.4%) HCV and TTV coinfection whereas four (8.8%) were coinfected with GBV-C/HGV and TTV. No differences regarding age, gender, previous surgery and number of transfusions were found between infected and uninfected patients within and between both groups. In conclusion, the prevalence of the viruses studied in predialysis may influence their prevalence in dialysis units.     

GB virus C/hepatitis G virus and TT virus infections among high risk renal transplant recipients in India.

BACKGROUND: GB virus C/hepatitis G virus (GBV-C/HGV) and TT virus (TTV) have been widely reported in patients with high parenteral risk such as haemodialysis and renal transplant recipients. The occurrence of these agents in association with hepatitis B virus (HBV) and hepatitis C virus (HCV), in Indian renal transplant recipients, is yet unreported. STUDY DESIGN: Molecular and serological markers of GBV-C/HGV and TTV were examined in addition to those for HBV, HCV and hepatitis D virus (HDV) in a selected group of seventy renal transplant recipients. HGV RNA detection was achieved using primers specific for the 5'NCR and NS5a regions of the genome. Anti-GBV-C/HGV antibody was detected using the mu plate anti-HG env kit (Roche, Germany). TTV DNA PCR was performed using primers specific for the coding region (method A) of the genome. In 50% of patients, TTV DNA was also tested for using primers specific for the non-coding region (method B). Host related factors such as age, alanine aminotransferase (ALT) levels, number of transfusions, haemodialysis sessions, and months following transplantation were also studied. RESULTS: Exposure rates to GBV-C/HGV, TTV (method A), HBV, HCV and HDV were 58.6, 32.9, 52.9, 54.3 and 2.9%, respectively. 'Active' infection as measured by viraemia and/or virus-specific antigenaemia for GBV-C/HGV, TTV, HBV and HCV was 52.9, 32.9, 15.7 and 52.9%, respectively. The majority of GBV-C/HGV and TTV infections were seen as co-infections with other hepatitis viruses. Single infection with GBV-C/HGV and TTV was seen in ten (14.2%) and eight (11.4%) patients, and was not associated with ALT elevation when compared to uninfected blood donors. Using univariate analysis, GBV-C/HGV RNA was significantly associated with > or =20 haemodialysis sessions. TTV DNA occurrence was not associated with any risk factors. CONCLUSIONS: There is a high occurrence of GBV-C/HGV and TTV in this select group of renal transplant recipients in India. These viruses mostly occurred in the context of co-infections with other hepatitis viruses. Long term effects of multiple hepatotropic viral infections need to be carefully documented in such transplant populations.     

检测病毒性肝炎患者血清中SEN病毒及其临床意义

目的：检测病毒性肝炎患者血清中SEN病毒D和H(SENV-D、SENV-H),并探讨其临床意义。方法：采用巢式聚合酶链反应法（nPCR）检测甲、乙、丙、戊型肝炎和非甲－戊型肝炎患者血清中SENV-D和SENV-H DNA。结果：在180例病毒性肝炎患者血清中，SENV-D和SENV-H检出率分别为17.2%(31/180)和5.6%(10/180)，总检出率为18.3%(33/180)、甲、乙、丙、戊型肝炎患者的SENV-D/H检出率高于非甲－戊型肝炎患者。从甲、乙、丙、戊型肝炎和非甲－戊型肝炎患者分离的SENV-D/H核苷酸序列，与SENV-D/H原型株比较，其同源性在94％以上。甲、乙、丙和戊型肝炎患者有无SENV-D/H合并感染，其血清生化学指标无明显差异。结论：SENV-D/H可能不是非甲-戊型肝炎的病原，甲、乙、丙和戊型肝炎患者合并感染SENV-D/H并不加重病情。     

Hepatitis G virus (HGV): current perspectives

Five viruses are usually associated with hepatitis in humans: A-E. In addition to these viruses as aetiological agents of hepatitis, there remain a number of patients with hepatitis in whom no virus could be identified. It was therefore postulated that there may be other agents which may be causing hepatitis. Recently, two viruses have been associated with hepatitis: hepatitis G virus (HGV), and transfusion transmissible virus (TTV). Hepatitis G virus (HGV) is a single stranded RNA virus which represents a newly discovered virus belonging to the flavivirus family. HGV is distinct from hepatitis C virus (HCV) and the newly discovered GBV-A and GBV-B agents, while GBV-C represents an isolate of HGV. The structure of the HGV genome resembles that of HCV. HGV replicates in peripheral blood cells, while replication in liver cells has not been observed till date. Diagnosis of HGV infection is mainly by use of polymerase chain reaction (PCR), as serological techniques are still being developed. Epidemiological data indicate that the virus is prevalent throughout the world, including India and is transmitted via blood/blood products, sexually and vertically from infected mothers to children. The relationship between infection with the virus and presence of liver pathology is controversial and has not been proven beyond doubt, as majority of patients with HGV have no detectable evidence of disease.     

TT virus infection in patients with chronic hepatitis B or C: influence on clinical, histological and virological features

Concomitant infection with TT virus and hepatitis B virus (HBV) or hepatitis C virus (HCV) is common. However, the effect of TTV infection on chronic hepatitis B or C is unknown. The prevalence of TTV infection, the effect of TTV infection on the clinical, histological and virological features of patients with chronic hepatitis B or C, and the influence of TTV infection on the HCV response to interferon alfa therapy were studied. A total of 100 asymptomatic hepatitis B surface antigen carriers, 220 patients with HBV-related chronic liver diseases, and 110 patients with chronic hepatitis C treated with interferon alfa (3 million units subcutaneously three times a week for 24 weeks) were enrolled. Serum HCV RNA and serum TTV DNA were detected by the polymerase chain reaction (PCR). Serum HBV DNA and serum HCV RNA level were quantified by branched DNA assays. Infection with TTV was detected in 21.5% of HBV carriers and 37% of HCV carriers. TTV infection had little effect on the clinicopathological course of chronic HBV infection. In chronic hepatitis C, clinical features, histological severity, serum HCV RNA levels, and the response to interferon alfa therapy did not differ between those with and without TTV infection. The loss of serum TTV DNA did not correlate with the biochemical response as did in the loss of serum HCV RNA. In conclusion, TTV infection is found frequently in patients with chronic hepatitis B or C in Taiwan; however, coinfection with TTV does not affect the clinicopathological course of chronic hepatitis B or C and the response to interferon alfa therapy.     

Etiology of sporadic acute viral hepatitis in Taiwan: the role of hepatitis C virus, hepatitis E virus and GB virus-C/hepatitis G virus in an endemic area of hepatitis A and B.

The etiology of sporadic acute hepatitis was studied in 334 consecutive patients from Taiwan (237 men and 97 women, aged 16-81 years), with emphasis on the role of hepatitis C virus (HCV), hepatitis E virus (HEV), and GB virus-C/hepatitis G virus (GBV-C/HGV) in acute non-A, non-B (NANB) hepatitis and in HBsAg carriers with superimposed acute hepatitis. According to the conventional diagnostic criteria, there were 12 cases (3.6%) of acute hepatitis A, 17 cases (5.1%) of acute hepatitis B, 128 cases (38.3%) of acute NANB hepatitis, and 177 cases (53.0%) of acute hepatitis in HBsAg carriers (those who were HBsAg positive but IgM anti-HBc negative). Among 128 cases of acute NANB hepatitis, 70 (54.7%) had acute hepatitis C (HCV RNA positive), 5 (3.9%) had acute hepatitis E (IgM anti-HEV positive), and the other 53 (41.4%) were presumably acute hepatitis non-A-E. The prevalence of acute hepatitis A, B, E, and non-A-E showed no significant sex difference, whereas acute hepatitis C was significantly more prevalent in females. The prevalence of acute hepatitis A and B decreased and that of acute hepatitis C increased significantly with increasing age. In contrast, acute hepatitis E and non-A-E showed no significant age predominance. Of 177 HBsAg carriers with acute hepatitis, 64 (36.1%) demonstrated non-B hepatotropic virus superinfection, with HCV being the most common (60.9%), followed by hepatitis D, E, and A viruses, and the other 55 (31.1%) and 58 (32.8%) were presumed to have acute exacerbation of chronic hepatitis B or superimposed acute hepatitis non-A-E, respectively. Serum GBV-C/HGV RNA was detected in 3-4% of acute hepatitis non-A-E cases, suggesting its limited role in these cases.     

Detection of hepatitis G virus RNA in patients with hepatitis B,hepatitis C,and non-A-E hepatitis by RT-PCR using multiple primer sets

Hepatitis G virus(HGV)/GB virus C(GBV-C) is a newly identified virus associated with human hepatitis. The preliminary prevalence studies of HGV infection in Japan were entirely based on the detection of HGV RNA by RT-PCR. However, the selection of the different primer sets in such assay may influence sensitivity of the test because of the extensive genetic heterogeneity of HGV, and influence the estimation of the prevalence of HGV. To address this potential problem, we designed two primer sets from well conserved domains in the 5′NC and NS5 regions of HGV genome, and tested them together with the NS3-derived primer set in RT-PCR for their ability to detect HGV RNA in serial dilution of synthetic viral RNA templates. Subsequently, we used these three primer sets to detect HGV RNA in the sera of 371 Japanese patients with hepatitis B, hepatitis C, and non-A-E hepatitis. The results indicated that the primer set derived from the 5′NC region appeared to be most effective in detecting HGV RNA. The results also showed that only two out of the 126 patients (1.6%) with non-A-E hepatitis were positive for HGV RNA although the RNA were detected more frequently in patients with hepatitis B (2/38; 5.3%) and hepatitis C (17/207; 8.2%), suggesting that HGV is not a common causative agent for non-A-E hepatitis in Japan. J. Med. Virol. 52:385–390, 1997. © 1997 Wiley-Liss, Inc.     

GBV-C/hepatitis G virus in acute nonA-E hepatitis and in acute hepatitis of defined aetiology in Italy

The role of GBV-C/HGV in the aetiology of acute non A-E hepatitis and its impact on the course of acute hepatitis of defined aetiology were investigated by detecting viral RNA by RT-PCR and antibody to the E2 protein of GB virus C (anti-E2) by EIA. Ninety-eight patients with acute nonA-E hepatitis, 35 patients with acute hepatitis A, 63 with acute hepatitis B, 29 with acute hepatitis C and 270 controls were enrolled in this study. The prevalence of GBV-C/HGV RNA was similar among patients with acute nonA-E hepatitis (3.1%), with acute hepatitis A (2.9%), and controls (3.7%), but significantly higher (P < 0.05) among those with hepatitis B or C (19.0% and 48.3%, respectively). Similar figures were obtained considering the total rate of GBV-C/HGV exposure (viral RNA or anti-E2 positivity). The majority (24/30 or 80%) of GBV-C/HGV RNA positive patients reported a parenteral source of exposure whereas the remaining 20% denied having known risk factors. The liver function test values and the rate of chronic hepatitis B and C were similar in patients co-infected and in those not co-infected with GBV-C/HGV. This study excludes a significant role of GBV-C/HGV infection in the aetiology of acute nonA-E hepatitis in Italy. Concomitant GBV-C/HGV and HBV or HCV infection does not worsen the clinical course of illness among patients with acute hepatitis.     

Effects of GB virus-C/hepatitis G virus on hepatitis B and C viremia in multiple hepatitis virus infections

Summary.  We found that patients with dual HBV and GBV-C/HGV infection had comparable serum HBV DNA positivity and mean virus concentration compared with age-matched HBV carriers, and those with triple infection had a significantly lower HBV DNA positivity. Serum HCV RNA positivity and mean virus titer were similar between HCV carriers with or without GBV-C/HGV co-infection, and those with GBV-C/HGV co-infection seemed to have a lower serum ALT level. These data suggest that GBV-C/HGV infection exerts no significant suppression on levels of chronic hepatitis B or hepatitis C viremia. Accepted December 4, 1997 Received September 8, 1997     

Genetic heterogeneity and molecular epidemiology of GB virus C/hepatitis G virus in China

OBJECTIVE: The inter- and intrapatient genetic variation of GB virus C (GBV-C)/hepatitis G virus (HGV) was investigated to characterize the molecular epidemiologic profile of GBV-C/ HGV infection in China, an area endemic for viral hepatitis. The intrapatient variation of hepatitis C virus (HCV) from the same patients was compared to that of GBV-C/HGV. STUDY DESIGN/METHODS: GB virus C/HGV RNA was amplified by polymerase chain reaction in 88 patients with hepatitis C, hepatitis B or presumed non-A-E hepatitis from three cities in China. Five clones of the GBV-C/HGV NS3 region were sequenced from each GBV-C/HGV RNA-positive patient. The corresponding region of HCV was also sequenced from patients co-infected with HCV. Representative sequences of the GBV-C/HGV NS3 region from each patient and those of isolates from other continents were subjected to phylogenetic analyses. RESULTS: GB virus C/HGV was detected in 22 (25.25%) of 88 patients: 9 (21.4%) of 42 patients with presumed non-A-E hepatitis, 10 (27.7%) of 36 patients with hepatitis C, 3 (30.0%) in 10 patients with hepatitis B and C, and in none of 60 volunteer blood donors. The extent of nucleotide variation was less between Chinese isolates (2.4-17%; median, 10.4%) than between Chinese isolates and seven isolates from outside China (10.5-19.5%; median, 15.3%). Intrapatient sequence variation ranged from 0 to 1.75%, with a mean of 0.57 +/- 0.51%. Phylogenetic analysis grouped most Chinese isolates into four geographically specific clusters with a divergence of 10% to 16% from each other. The ratio of nonsynonymous to synonymous substitutions of GBV-C/HGV (Ka/Ks 0.019) was much lower than for HCV (0.071) in the same patients. CONCLUSION: Chinese isolates of GBV-C/HGV are genetically distinct. There are local strains as well as shared strains between different locales. The extent of amino acid sequence conservation suggests strong selection against nonsynonymous substitutions in the GBV-C/HGV genome.     

Molecular characteristic-based epidemiology of hepatitis B, C, and E viruses and GB virus C/hepatitis G virus in Myanmar

We carried out a molecular characteristic-based epidemiological survey of various hepatitis viruses, including hepatitis B virus (HBV), hepatitis C virus (HCV), hepatitis E virus (HEV), and GB virus C (GBV-C)/hepatitis G virus (HGV), in Myanmar. The study population of 403 subjects consisted of 213 healthy individuals residing in the city of Yangon, Myanmar, and the surrounding suburbs and 190 liver disease patients (155 virus-related liver disease patients and 35 nonviral disease patients). The infection rates of the viruses among the 213 healthy subjects were as follows: 8% for HBV (16 patients), 2% for HCV (4 patients), and 8% for GBV-C/HGV (17 patients). In contrast, for 155 patients with acute hepatitis, chronic hepatitis, liver cirrhosis, or hepatocellular carcinoma, the infection rates were 30% for HBV (46 patients), 27% for HCV (41 patients), and 11% for GBV-C/HGV (17 patients). In the nonviral liver disease group of 35 patients with alcoholic liver disease, fatty liver, liver abscess, and biliary disease, the infection rates were 6% for HBV (2 patients), 20% for HCV (7 patients), and 26% for GBV-C/HGV (9 patients). The most common viral genotypes were type C of HBV (77%), type 3b of HCV (67%), and type 2 of GBV-C/HGV (67%). Moreover, testing for HEV among 371 subjects resulted in the detection of anti-HEV immunoglobulin G (IgG) in 117 patients (32%). The age prevalence of anti-HEV IgG was 3% for patients younger than 20 years and 30% or more for patients 20 years of age or older. Furthermore, a high prevalence of anti-HEV IgG (24%) was also found in swine living together with humans in Yangon. These results suggest that these hepatitis virus infections are widespread in Myanmar and have led to a high incidence of acute and chronic liver disease patients in the region.     

庚型肝炎病毒IgM抗体检测方法的建立及其临床意义

目的建立一种早期、快速诊断庚型肝炎的血清学检测方法。方法以辣根过氧化物酶标记庚型肝炎病毒（ＨＧＶ）多肽ＮＳ３,ＮＳ５区段抗原,建立了捕获酶联免疫吸附试验（ＥＬＩＳＡ）,用于检测血清中ＨＧＶＩｇＭ抗体。结果本法不受特异性ＩｇＧ的竞争和类风湿因子的干扰;与其它致肝炎的病毒（ＨＡＶ、ＨＢＶ、ＨＣＶ、ＨＥＶ、ＣＭＶ、ＥＢＶ）无交叉反应。检测４６例非甲、乙、丙、戊型肝炎患者血清,抗－ＨＧＶＩｇＭ阳性１４例,阳性率３０．４３％,其中,６例同时为ＨＧＶＲＮＡ阳性,阳性符合率为４２．８６％（６／１４）,检测１２例庚型肝炎病人双份血清,其中,急性期血ＨＧＶＩｇＭ抗体均为阳性。结论该法检测ＨＧＶＩｇＭ抗体特异性强,敏感性高,且简便快速,适用于临床对庚型肝炎新近感染的早期诊断,有推广应用价值。     

Prevalence of hepatitis G virus in Pakistani children with transfusion dependent beta- thalassemia major

We ought to obtain data on the prevalence of the newly discovered tranfusion transmittable hepatitis G virus in polytransfused b- thalassemia major children. Each individual had received multiple blood transfusions, from 12 to 36 per year. No documentation of prior hepatic infection was available. Serum samples were collected prospectively from the randomly selected subjects and were analyzed for HGV RNA by polymerase chain reaction using primer specific for two different regions of the HGV genome. Among the 100 individuals examined 21 were positive for HGV RNA. Four patients had evidence of dual infection, both HGV RNA and HCV RNA were isolated from their sera. While in one sample presence of both HGV RNA and HBV DNA was established. Only one child was positive for hepatitis E antibodies. The sera of 10 children were reactive for hepatitis B surface antigen whereas 35 individuals were positive for hepatitis C virus antibody. The ALT levels were variable in HGV infected children. Four out of 16 (25%) showed peak ALT levels of 218 IU/I, 8/16 (50%) children demonstrated slightly elevated ALT levels whereas 25% individuals showed normal ALT levels. Alkaline Phosphatase levels were elevated in 90% of the children and 20% patients of this series also had higher GGT levels. The observed AP levels were not statistically different among HGV, HGV/HCV or HGV/HBV groups. Even though the ALT levels were deranged in the children with HGV alone but none of the children had demonstrated symptoms of liver disease, their direct and total bilirubin levels were normal and no complain of jaundice was recorded. In conclusion, our findings suggested that like other blood borne hepatic viruses, HGV is also prevalent in the high risk group of multiple transfused patients in Pakistan but our results support the absence of any causal relationship between HGV and hepatitis.     

TTV infection and its relation to serum transaminases in apparently healthy blood donors and in patients with clotting disorders who have been investigated previously for hepatitis C virus and GBV-C/HGV infection in Belgium

A novel DNA virus, TT virus (TTV), has been proposed as a possible etiologic agent for non A-E hepatitis. The aim of the present study was to determine the prevalence of TTV infection using PCR in healthy blood donors and in patients with clotting disorders who have been investigated previously for GBV-C/HGV and HCV infection in Belgium. In this study, PCR using primers proposed by Takahashi et al. [(1998) Hepatology Research 12:233-239] proved far more sensitive than those used by Okamoto et al. [(1998) Journal of Medical Virology 56:128-132]. The sequence of the PCR products showed 87% identity to the published sequence. TTV was present in 29.7% of healthy blood donors, a figure intermediate between the low rate of infection observed in Scotland and the high rates in the Far East. TTV was detected in 46.5% of 127 patients studied with clotting disorders as compared to 79.5% for HCV and 11.8% for GBV-C/HGV infection. However, there was no impact on the level of serum transaminases. Treatment with interferon for HCV infection co-infected with TTV suppressed temporarily serum TTV DNA. Therefore, it was concluded that TTV DNA is detected frequently in serum of healthy blood donors in Belgium and more often in patients with clotting disorders. TTV does not cause liver disease or contribute to the severity of liver disease.     

GBV-C/HGV infection in chronic hepatitis C patients: Its effect on clinical features and interferon therapy

A novel virus (GBV-C/HGV) may be associated with some liver diseases including fulminant hepatitis and acute and chronic hepatitis. On the other hand, many investigations showed that this infection does not contribute to liver disease. GBV-C/HGV has been found to occur in association with infection with other hepatitis viruses. We investigated the effect of GBV-C/HGV infection on the clinical features and interferon treatment in patients with chronic hepatitis C. A total of 262 hepatitis C virus (HCV) RNA positive patients with chronic hepatitis were examined in this study. The detection of serum GBV-C/HGV RNA was done by RT-PCR using specific primers from the NS5 regions. Interferon-alpha was given at a dose of 6 MU/day for 16 or 24 weeks. A responder was defined as a patient with ALT normalization and HCV RNA disappearance after treatment. GBV-C/HGV RNA was detected in 28 (11%) patients. No significant difference was detected in clinical features (age, sex, liver-related biochemical tests, and histological examination) between the 28 GBV-C/HGV-positive patients and the GBV-C/HGV-negative patients. Using interferon therapy for hepatitis C, the responder rates of GBV-C/HGV-positive and -negative patients were 14% and 20%, respectively. Of the 28 patients with GBV-C/HGV RNA, GBV-C/HGV RNA was tested after interferon therapy in 16 and of these GBV-C/HGV RNA was not detected in nine patients after therapy. These findings suggest that GBV-C/HGV infection dose not affect the clinical features in patients with HCV and the efficacy of interferon therapy for chronic hepatitis C. J. Med. Virol. 55:98–102, 1998. © 1998 Wiley-Liss, Inc.     

Seroepidemiology of TT virus, GBC-C/HGV, and hepatitis viruses B, C, and E among women in a rural area of Tanzania

The seroprevalence and determinants of hepatitis B, C, and E virus infection, and of GBV-C/hepatitis G virus and TT virus infection were investigated among women from a rural area of northeastern Tanzania. High seroprevalence rates were found for TTV (74%), HBV (74%), and GBV-C/HGV (35%), whereas 7% of the women had evidence of HCV and HEV infection. The majority of TTV DNA sequences in the study population belonged to the genotypes 1 or 2. One sequence seems to represent a new subtype of genotype 4. The GBV-C/HGV sequences either belonged to the genomic Group 1b or to the recently described Group 4. In multivariate analysis, the detection of TTV DNA was associated significantly with a larger number of children in the household and with older age. A history of injections of contraceptive hormones was an independent risk factor for HCV infection. The findings on TTV are consistent with fecal-oral transmission, and recurrent infections may occur in adults.