利用双扩增聚合酶链反应检测非甲非乙型肝炎患者血清中丙型肝炎病毒RNA

利用丙型肝炎病毒（ＨＣＶ）５’－端序列合成两对引物，建立了灵敏、特异的ＨＣＶＲＮＡ双扩增聚合酶链反应检测方法。用此方法及第二代Ａｂｂｏｔｔ酶联抗－ＨＣＶ检测试剂盒，检测了４４例非甲非乙型肝炎患者血清及１０名抗－ＨＣＶ阴性健康人。在４４例患者中，４１例（９３％）ＨＣＶＲＮＡ阳性，３６例（８２％）抗－ＨＣＶ阳性，３３例（７５％）ＨＣＶＲＮＡ、抗－ＨＣＶ全部阳性。３例ＨＣＶＲＮＡ阴性，但抗－ＨＣＶ阳性，另外，有８例抗－ＨＣＶ阴性，ＨＣＶＲＮＡ阳性。１０名健康人ＨＣＶＲＮＡ均为阴性。结果表明，大部分（９２％）抗－ＨＣＶ阳性患者带有ＨＣＶ，但为了检测所有病毒血症患者，抗－ＨＣＶ检测是不够的，利用双扩增ＰＣＲ方法检测ＨＣＶＲＮＡ对于抗－ＨＣＶ阴性患者的诊断是非常有用的。     

Detection of HCV RNA in saliva, urine, seminal fluid, and ascites.

Approximately half of the patients with type C hepatitis do not have a history of parenteral exposure. The route of nonparenteral infection remains unknown. To evaluate the possible role of body fluids, the existence of hepatitis C virus (HCV) RNA in saliva, urine, seminal fluid, and ascites was examined by "nested" polymerase chain reaction (PCR). Amplification of the HCV 5' noncoding sequences was carried out. The amplified product was confirmed by Southern blot hybridization and restriction endonuclease digestion. Among 34 patients with chronic liver disease who were positive for anti-HCV and serum HCV RNA, the prevalence of HCV RNA in body fluids was 100% (7/7) in ascites, 48% (15/31) in saliva, 24% (4/17) in seminal fluid, and 7% (2/29) in urine. The body fluids collected from 3 healthy subjects and 5 patients with chronic liver disease who were positive for anti-HCV but negative for serum HCV RNA were all negative for HCV RNA. Hence, the potential infectivity of body fluids in patients testing negative for serum HCV RNA can probably be discounted. Conversely, the presence of HCV RNA in saliva and seminal fluid of patients positive for serum HCV RNA suggests sexual and household contact as likely modes of nonparenteral transmission of type C hepatitis. Furthermore, the high prevalence of HCV RNA in ascites and saliva may have important implications in medical and dental practice.     

Antibody responses to the hepatitis C virus E2 protein: Relationship to viraemia and prevalence in anti-HCV seronegative subjects

A small proportion of patients with chronic hepatitis C virus (HCV) infection show no serological responses to the HCV polypeptides incorporated in commercial III generation immunoassays. To determine whether sera from these subjects contain antibodies to the highly immunoreactive second envelope polypeptide E2, which is not included in current anti-HCV assays, we studied 59 anti-HCV negative subjects who were found consistently to be HCV RNA positive by polymerase chain reaction (PCR). Controls included 167 anti-HCV seropositive patients with or without serum HCV RNA and normal subjects. Antibodies to the E2 region were sought for by ELISA using the following antigens: a full length E2 protein expressed in insect cells using a baculovirus vector and extracted under denaturing conditions (dE2), and a C-terminal truncated soluble E2 (sE2) protein (a.a. 390–683), also expressed with a baculovirus vector, containing a signal peptide of rabies virus G protein which allows its secretion into the culture supernatant. Sera from only two (3.4%) of the 59 anti-HCV negative, HCV RNA positive patients recognised sE2 and none dE2. In sharp contrast, 82% of seropositive, viraemic patients recognised sE2 and 60% dE2, the difference in immunoreactivity being statistically significant (P < 0.0003). A significantly lower proportion of sera from anti-HCV positive, HCV RNA negative subjects recognised either sE2 or dE2 (16% and 13%, respectively, P < 0.000001). Healthy controls were consistently negative. These results indicate that antibody responses to predominantly conformational epitopes on the HCV E2 protein are common in patients with chronic HCV infection and are strictly related to the presence of circulating viral genomes. In contrast, only a minor proportion of HCV RNA positive patients, but anti-HCV seronegative by commercial immunoassays, have humoral immune responses to the HCV E2 region. J Med Virol 51:1–5, 1997. © 1997 Wiley-Liss, Inc.     

Sensitivity of a modified version of the ARCHITECT Anti-HCV test in detecting samples with immunoblot-confirmed, low-level antibody to hepatitis C virus.

BACKGROUND AND OBJECTIVES: Compliance with current regulations regarding the prevention of hepatitis C virus (HCV) transmission in the blood transfusion setting requires the use of sensitive assays for HCV antibody (anti-HCV) detection, which should, ideally, identify any donor having had prior contact with the virus. Therefore, low-level anti-HCV positive blood units should be detected by the screening assays, even those reflecting a past and resolved infection. To assess the sensitivity of two versions of an automated chemiluminescent microparticle immunoassay (CMIA) for anti-HCV screening (ARCHITECT Anti-HCV), 113 single serum samples containing low levels of anti-HCV, assessed by two immunoblot tests, were selected from 3686 samples received for confirmation of HCV infection by a reference laboratory over a 2-year period. MATERIALS AND METHODS: The panel included 17 samples with HCV RNA detected by the polymerase chain reaction (PCR) and 96 PCR negative samples with either positive or indeterminate (anti-Core and anti-NS3 alone) results by immunoblot. RESULTS: All but 13 specimens (100/113, 88.5%) were detected by the current version of the ARCHITECT Anti-HCV assay and 10 additional samples (110/113, 97.3%) tested positive in a modified version of the test. CONCLUSION: The results showed that the modification introduced in the ARCHITECT Anti-HCV assay achieves a significant sensitivity improvement including samples with low-level anti-HCV which are either PCR positive or negative.     

Accuracy of HCV-RNA PCR tests for diagnosis or exclusion of vertically acquired HCV infection

The aim of the study was to estimate the sensitivity, specificity, positive (PPV) and negative (NPV) predictive values, and likelihood ratios for HCV-RNA PCR tests for the early diagnosis or exclusion of HCV infection in vertically exposed children. Data were included for children with confirmed HCV infection status from a European multi-center study. Confirmation was dependent on antibody status at or beyond 18 months, the 'gold standard' measure of infection status against which the use of qualitative HCV-RNA PCR tests was assessed. Of the 547 children included in this analysis, 193 were HCV-infected and 354 were not. Sensitivity of the HCV-RNA PCR test was low at birth (22%), but increased to 85% by 6 months. Specificity of RNA PCR was constant over age at 98%. The PPV of the PCR test rose from 33% at birth to 78% at 9 months of age, while NPV ranged from 96% to 99%. The high positive likelihood ratios from 1 month of age indicate strong evidence to diagnose infection but the negative likelihood ratios were consistent with weak evidence to exclude infection. The results suggest that the first qualitative HCV-RNA PCR test should be delayed until after the first month of life given the low sensitivity in the first few weeks. Although a negative test result after this time indicates probable absence of infection, this should be confirmed with a negative anti-HCV antibody test between 9 and 15 months of age as negative PCR results can be observed in infected children with fluctuations in viremia.     

Epidemiologic survey and genetic analysis of endemic hepatitis C virus infection in a Japanese town with a high prevalence of hepatitis B virus carriers

Mass screening for hepatitis C virus antibody was carried out in 875 inhabitants (313 men and 562 women) of a town in Japan with a high rate of hepatitis B virus infection. The overall rate of positivity for anti-HCV was 8.8% (6.4% in men and 10,1% in women). The rate of positivity for hepatitis B virus surface antigen was 11.2%. Five subjects (0.6%) were positive for both markers. HCV-RNA was detected in 65 (88.4%) of 77 individuals who were positive for anti-HCV and in 1 (1.5%) of 60 individuals negative for anti-HCV. The genotype of the HCV genome was determined by PCR analysis using type-specific primers in 60 individuals. HCV type 1b was detected in 51 subjects (85%), type 2a in 3 subjects (5%), and type 2b in 6 subjects (10%). None of the individuals was infected with more than one genotype. The nucleotide sequences of the partial nonstructural 5 region of HCV type 1b genotype obtained from 6 individuals showed at least 92.0% homology in the nucleotide sequence, and 94.8% homology in the amino acid sequence. Homology among these clones was greater than their homology with previously described type 1 b sequences. The findings suggest that there was a specific local origin of HCV infection, although it was not possible to identify any single source of HCV infection. The results also indicate the presence of asymptomatic HCV carriers. © 1995 Wiley-Liss, Inc.     

Prevalence of hepatitis C virus infection among hemodialysis patients at a tertiary-care hospital in Mexico City, Mexico

We determined the prevalence of hepatitis C virus (HCV) in hemodialysis patients by antibody testing and HCV RNA determination by PCR. A total of 149 patients with kidney failure with replacement therapy were tested. The prevalence of anti-HCV was 6.7% (10 of 149 patients), and viremia was detectable in 8 of 149 (5%) patients. Three of 149 patients (2%) were anti-HCV negative with detectable HCV RNA.     

Diagnosis of hepatitis C virus (HCV) infection and laboratory monitoring of its therapy.

BACKGROUND: Just after the identification and characterization of hepatitis C virus (HCV) in 1989, tests for the detection of HCV antibodies or HCV RNA in serum were developed. The enzyme-linked immunosorbent assays (ELISAs) and confirmatory/supplemental analytical antibody tests were improved in sensitivity and specificity with the development of further generations of these assays. Application of molecular tests for detecting, quantifying, and characterization of the infecting virus became very important in management of HCV infection. OBJECTIVE AND DESIGN: This review summarizes the assays developed for the diagnosis and management of HCV infection. Strategies for the diagnosis and monitoring with the advantages and disadvantages of the assays based on the setting and goal are discussed according to data in the literature and our experience. Results: Specific laboratory diagnostic tests for hepatitis C virus infection may be discussed under two titles: (i) Serological antibody tests which detect anti-HCV in serum or plasma; (ii) Molecular tests which detect HCV RNA genome, investigate viral load, and determine the characteristics of the genome. Strategies in different laboratory settings which screen populations with different HCV prevalences vary. CONCLUSIONS: Anti-HCV positive result in a low-risk setting such as blood banks should be confirmed with an analytical antibody test. Then a HCV RNA test should be performed on serum of the person with a positive or indeterminate confirmatory test result. On the contrary, anti-HCV positive test result in high-risk population or a situation where HCV infection is suspected, it is likely to be true positive and confirmation with HCV RNA test will be significant. Quantitative HCV RNA test and genotyping should be performed if therapy is considered.     

Usefulness of the hepatitis C virus core antigen assay for screening of a population undergoing routine medical checkup

We studied the usefulness of the recently designed Trak-C assay for the detection and quantification of the hepatitis C virus (HCV) core antigen (Ag) for the screening of HCV infection in 4,201 subjects selected from 74,150 consecutive volunteers undergoing routine medical checkups. Subjects were selected for screening because they had risk factors (group II, n = 321) and/or elevated alanine transaminase activity (group I, n = 3847). Initially, the anti-HCV antibody assay and the Trak-C assay were performed on each patient. Subsequently, the Trak-C assay was performed only when the anti-HCV enzyme immune assay (EIA) was positive. Positive samples were further evaluated for anti-HCV antibodies by a third-generation strip immunoblot assay and for HCV RNA. Four samples (1.2%) from group II and 113 (2.9%) from group I were anti-HCV EIA positive. We also tested 33 subjects who previously tested positive for anti-HCV in our medical center. Among the 150 anti-HCV EIA-positive samples, the HCV core Ag result was in accord with the HCV RNA result in 146 cases (97.3%). When the EIA result was positive, the HCV core Ag concentration and the HCV RNA load were correlated (r(2) = 0.78; P < 0.001). Four samples with low viral loads were Trak-C negative but HCV RNA positive. Among the 2,395 anti-HCV EIA-negative serum samples collected during the first part of the study, 17 (0.7%) were found to contain very low levels of HCV core Ag (<8.5 pg/ml, the cutoff value being 1.5 pg/ml). All these samples were HCV RNA negative and considered to be false positives. This was confirmed by HCV core Ag neutralization analysis. The HCV core Ag assay is a useful method in the screening strategy of HCV infection and provides a reliable means of distinguishing between current and cleared HCV infections that is well correlated with HCV RNA testing.     

Hepatitis C virus infection among pregnant women in Yaounde,Cameroon: prevalence,viremia, and genotypes

Central Africa is considered to be an area of high endemic hepatitis C infection. To determine the prevalence of anti-HCV antibodies, HCV RNA, and the genotype distribution in Cameroon, 1,494 pregnant women attending antenatal care units in Yaounde, Cameroon were screened for HCV infection. Anti-HCV antibodies were detected with a 3rd generation ELISA (Monolisa anti-HCV plus version 2, BioRad, Richmond, CA). All anti-HCV antibody-positive sera were then tested with another 3rd generation ELISA (AxSYM) HCV version 3, Abbott Laboratories, Abbott Park, IL) and subsequently for HCV RNA (Amplicor HCV, Roche Diagnostics, Basel, Switzerland). Genotype was determined by phylogenetic analysis of the NS5b gene. Seventy-three pregnant women were found to be anti-HCV antibody positive by the first ELISA, but only 28 were anti-HCV positive by both ELISA. The prevalence of anti-HCV antibodies was thus 1.9% (28/1,494) (95% CI: 1.3-2.7%). 21/28 (75%) of the positive samples by both ELISA were HCV RNA positive. The 45 samples that were HCV antibody negative by the second ELISA were also HCV RNA negative. The HCV subtypes identified were 1a (24%), 2f (38%) and 4f (38%). In contrast to previous studies, anti-HCV antibodies were rare among pregnant women in Cameroon. The percentage of HCV seropositive pregnant women who had circulating HCV RNA was similar to that observed in Europe. Several HCV genotypes were found in Cameroon.     

Simultaneous detection of hepatitis C virus (HCV) core antigen and anti-HCV antibodies improves the early detection of HCV infection

To evaluate whether a new enzyme immunoassay developed for the simultaneous detection of hepatitis C virus (HCV) core antigen (Ag) and anti-HCV antibodies (anti-HCV Ab) (Monolisa HCV Ag/Ab ULTRA; Bio-Rad) could improve the early detection of HCV infection, we compared its sensitivity to that of anti-HCV, HCV core Ag, and HCV RNA assays. The populations studied included 12 blood donor samples positive for HCV RNA and HCV core Ag but negative for anti-HCV antibodies and 23 hemodialysis patients who developed anti-HCV Ab (seroconversion) during the follow-up. From these 23 individuals, 83 samples sequentially collected prior to seroconversion and 108 samples collected after seroconversion were tested. Six of 12 blood donations were positive by the HCV Ag/Ab assay. In the hemodialysis cohort, the 24 HCV RNA-negative samples were negative by the HCV Ag/Ab assay and 23 of the 59 HCV RNA-positive samples (39%) were positive. The HCV Ag/Ab assay detected HCV infection on average 21.6 days before the most sensitive antibody assay. The HCV Ag/Ab assay did not detect HCV infection as early as the HCV RNA assay (mean delay, 30.3 days) or HCV Ag assay (mean delays, 27.9, and 16.3 days by the HCV core Ag quantification assay and the HCV Ag blood screening assay, respectively). This new assay provides a notable improvement for the early detection of HCV infection during the so-called window period compared with anti-HCV Ab assays and could be a useful alternative to HCV RNA detection or HCV core Ag assays for diagnosis or blood screening when nucleic acid technologies or HCV core Ag detection are not implemented.     

肝病产妇丙型肝炎病毒母婴传播的可能性调查

对１９９１～１９９３年在南京市钟阜医院肝病产科住院的１０４７例肝病产妇中１２例丙型肝炎病毒抗体和／或丙型肝炎病毒核糖核酸阳性者，追踪观察了所生１２名婴儿的丙型肝炎病毒感染情况，发现１例抗－ＨＣＶ和ＨＣＶＲＮＡ均阳性的孕妇所生的婴儿，０、１、６和１２个月时抗－ＨＣＶ和ＨＣＶＲＮＡ均阳性，且该婴儿ＨＣＶ的血清型与母亲一致。结果提示，肝病产妇丙型肝炎病毒母婴传播是可能的，但不是主要的传播途径。     

Twenty-four mini-pool HCV RNA screening outside a blood transfusion setting: results of a 2-year prospective study

The usefulness of 24 mini-pool hepatitis C virus (HCV) RNA screening was evaluated in a 2-year prospective study carried out on a total of 6432 consecutive anti-HCV negative specimens in a routine diagnostic laboratory setting. A total of 268 mini-pools were tested using an automated commercial PCR assay for qualitative detection of HCV RNA, with a lower limit of detection of 50 IU/ml. Eighteen (0.28%) anti-HCV negative/HCV RNA positive serum samples obtained from 12 patients (all intravenous drug users), were detected. Ten patients responded to an invitation for follow-up testing. Five, three and one patient seroconverted in the first, second and third follow-up sample, respectively. One patient had not seroconverted by the end of the study period. The interval between the first HCV RNA positive sample and the first anti-HCV positive samples was 24–192 days. The costs of detecting a single anti-HCV negative/HCV RNA positive sample and a single anti-HCV negative/HCV RNA positive patient using the 24 mini-pool HCV RNA screening strategy were estimated to be around €643 and 965, respectively. It was shown that screening for HCV infection using the 24 mini-pool HCV RNA screening strategy can also be both useful and cost effective outside a blood transfusion setting.     

Variability of IgM response in hepatitis C virus infection

The IgM and IgG antibody response to various hepatitis C virus (HCV) antigens was studied in 8 patients who acquired posttransfusion HCV infection. IgM anti-HCV was detectable in only 4 of these patients, coincident with (1 patient) or later than (3 patients) the IgG anti-HCV response. Seven patients had initially decreasing IgG anti-HCV titres, indicating passive transfer of antibodies from donor to recipient. All 8 patients showed active IgG seroconversion, as demonstrated by increasing IgG anti-HCV titres, on average, 75 days after infection. Five years after infection, all patients were still reactive for IgG anti-HCV antibodies and 7 were positive for HCV RNA by the polymerase chain reaction (PCR). Two of these PCR positive patients were also reactive for IgM anti-HCV. It is concluded that the serology of HCV infection does not follow the classical pattern of IgM response preceding detection of IgG. The IgM response may be absent, late, or persistent after HCV infection. The serological diagnosis of recent HCV infection should be based on the polymerase chain reaction or rising IgG titres in at least 2 sequential patient blood samples. © 1993 Wiley-Liss, Inc.     

Detection of hepatitis C virus sequences in sera with controversial serology by nested polymerase chain reaction.

The specificity of first-generation enzyme-linked immunosorbent assays (ELIAs) for antibody detection in individuals with hepatitis C virus (HCV) infection has been questioned in some pathological situations. We observed a surprisingly high prevalence of anti-HCV antibodies in alcoholic patients, and thus, false-positive reactions in anti-HCV tests were strongly suspected. The introduction of new epitopes, particularly a core protein, C22 (second-generation tests), seems to increase the sensitivity of anti-HCV detection. In order to study the specificity of the second-generation tests, 60 serum samples from alcoholic patients found to be positive by the first-generation anti-HCV ELISA (Ortho) were reexamined by a second-generation anti-HCV enzyme immunoassay (Abbott) and a recombinant immunoblot assay (RIBA II; Chiron). Fifteen serum samples gave contradictory results when they were tested by the two assays. We performed nested polymerase chain reactions (PCRs) to confirm that the discrepancies that we observed could be due to the presence of low levels of anti-HCV antibodies, which were detected by a more sensitive test, or to unspecific positive reactions. Nested PCR revealed the presence of HCV RNA sequences in all anti-HCV-positive sera or sera that were weakly positive by ELISA. Anti-HCV positive by RIBA II was always correlated with the presence of viral RNA in serum, but HCV RNA was detected in RIBA II-negative sera. These results indicate that the specificity of the second-generation tests is an important improvement but that an HCV infection can still persist without detectable antibodies. PCR remains the reference assay to clear up controversial serology results and to detect HCV infection in patients with no anti-HCV-detectable immune response.     

血清HCV RNA检测在预防输血后丙型肝炎中的意义

目的 探讨血清HCV RNA检测在预防输血后丙型肝炎中的意义。方法 用ELISA法检测2000年1月至2003年12月末抗．HCV阴性的全血标本56400份次，再进行RT-PCR（荧光适时技术）检测HCV RNA，并对输过HCV RNA筛查阴性血液的患者进行追查。结果 HCVRNA阳性率为2．5‰（146／56400）。对输过HCVRNA筛查阴性血液的患者追查结果，无一例发生输血后丙型肝炎。结论 对抗-HCV阴性的血液标本用敏感的试剂进行HCV RNA检测在预防输血后丙型肝炎中不但有效，而且可行。