The prevalence of hepatitis G virus (HGV)-RNA and HGV-E2 antibodies was studied in a cohort of Dutch hemophilia patients in relation to clotting products used, age, and coinfection with hepatitis C. Between 1991 and 1995, blood samples were taken from 294 patients with hemophilia A, B, or von Willebrand disease. From each patient one fresh frozen sample was tested for HGV cDNA polymerase chain reaction (PCR) and HCV cDNA PCR. Alanine aminotransferase (ALT) tests were performed on plasma samples of all patients. The presence of HGV-E2 antibodies was tested on plasma samples from a subset of 169 patients representing all age groups. Based on the origin and viral safety of the products used, three subgroups of patients were distinguished. Group A: patients who used viral noninactivated factors derived from small and large donor pools; group B: patients who used factors prepared with inadequate viral inactivation techniques derived from small and large donor pools; and group C: patients treated only with optimally viral inactivated large pool clotting factor or recombinant clotting factor concentrate. The prevalence of HGV-RNA was 18%. In group A patients the prevalence was 71%, in group B 50%, and in group C 6%. When related to age, the highest prevalence of HGV-RNA (35%) was seen in patients born between 1980 and 1989. The prevalence of HGV-E2 antibodies increased with age. Of HGV-RNA–negative patients born before 1950, 96% tested positive. HGV viremia did not affect ALT levels, neither in HCV-RNA positive nor in HCV-RNA negative patients. HGV infection is frequently seen in patients with hemophilia. In older age groups a lower rate of HGV-RNA positivity is seen coinciding with a higher rate of antienvelope antibodies.

© 1998 by The American Society of Hematology.

IN THE PAST, HEMOPHILIA patients have been infected with hepatitis C virus (HCV), hepatitis B virus (HBV), and human immunodeficiency virus (HIV)1-3 after treatment with nonviral inactivated clotting factor products derived from human plasma. Since the introduction of dry heat-treated clotting products in the mid 80s, HIV transmission has no longer been observed. Introduction of wet heating or solvent detergent inactivation steps in the manufacturing process of clotting products has shown them to be effective in preventing HCV transmission.2 These inactivation steps are relatively ineffective in reducing the risk of transmission of nonenveloped viruses such as hepatitis A virus (HAV) and parvo B19 virus.4 5 

Recently, the hepatitis G virus (“HGV,” identical to “GBV-C”) has been characterized as an agent potentially causing non A-E hepatitis. HGV is a widely distributed RNA virus related to HCV and other flaviviridae.6-9 In several studies, it has been shown that 1% to 3% of blood donors test HGV-RNA positive,6,10,11 while approximately 10% of blood donors have detectable antibodies against the putative envelope protein (E2 antibodies).10,12 HGV is also highly prevalent among intravenous (IV) drug users, of whom approximately 40% test positive for E2 antibodies and another 40% are found to be HGV-RNA positive.10,13 HGV is shown to be transmitted parenterally through blood and blood products,14-17 as well as vertically from mother to child.18,19 Therefore, recipients of blood products, such as hemophilia and thalassaemia patients, have been shown to be at risk for HGV infection.6 20-24 

Most HGV infections appear to be asymptomatic. A few cases of fulminant hepatitis have been reported, but it remains unclear whether the hepatitis was actually caused by HGV.9,25,26 Anti-E2 seroconversion seems to be associated with viral clearance.10 12 

A coinfection of HGV with HCV, often seen in patients with hemophilia, seems not to affect the course of HCV infection14,27,28 or the response to interferon-alpha therapy.29 

In the present study, we determined from among Dutch hemophilia patients (1) the prevalence of HGV-RNA, HCV-RNA, and E2 antibody reactivity, (2) the effect of viral inactivation of blood products on the prevalence of HGV-RNA and E2 antibody, and (3) the effect of HGV viremia on the alanine transaminase (ALT) levels in HCV-RNA positive and HCV-RNA negative patients.

Patients

Blood samples were taken from 294 patients. Fresh frozen plasma samples from a total of 252 hemophilia A, 34 hemophilia B, and 8 von Willebrand disease patients, born between 1919 and 1993, were tested for HGV-RNA. The plasma samples originally had been drawn for HCV polymerase chain reaction (PCR) testing in patients visiting the hemophilia center for annual check-ups. At the time of plasma sampling (1991 to 1995), none of the patients was receiving antiviral therapy for HCV infection.

For the anti-E2 assay, an equal number of patients from various age groups was selected (30 patients born before 1950, 30 patients born, respectively, in the period between 1950 and 1959, between 1960 and 1969, between 1970 and 1979, and between 1980 and 1989, and 19 patients born after 1990). From each age group, we tested the available samples from HGV-RNA positive patients and we added samples from HGV-RNA negative patients to complete the group of 30 patients. We had therefore selected plasma samples from 49 HGV-RNA positive and 120 HGV-RNA negative patients for detection of E2 antibodies.

Transfusion History

Based on the viral safety and the origin of the clotting factor concentrates, three categories of products can be distinguished. (1) Group A, nonviral inactivated small pool cryoprecipitate or nonviral inactivated large pool clotting factor concentrate (used until 1985); (2) group B, small pool cryoprecipitate (1985 to 1992) or large pool clotting factor concentrate (1985 to 1990), which were suboptimal viral inactivated (dry heating of lyophilized products at 60°C for 72 hours); (3) group C, large pool optimal viral inactivated clotting factor concentrate (SD treated, pasteurized) (1990 to present) or recombinant DNA-derived clotting factor concentrate (1992 to present).

Plasma Samples

From all 294 patients, a cell-free fresh frozen plasma sample had been obtained for HCV-RNA detection. Within 1 hour after venipuncture, the EDTA plasma samples had been frozen and stored at −70°C before HCV-RNA testing. Subsequently, the samples had been stored at −20°C until HGV-RNA and E2 antibody testing was performed.

Assays

HGV cDNA-PCR.

HGV-RNA detection by cDNA-PCR was performed with two sets of primers, one pair from the NS3 region and a second pair from the 5′-UTR. Nucleic acid was extracted from 0.1 mL plasma with proteinase K digestion and organic extraction, and subsequently reverse transcribed with random prime labelling, and amplified by PCR, as described previously.30 The amplification product from the NS3 region (primer set 77F/211R) was detected with oligomere detection with probe 152F, as described by Linnen et al.6 For amplification in the 5′ UTR primers NC1 (5′-CGG.C CA.AAA.GGT.GGT.GGA.TG-3′) and NC4 (5′-CCA. ACA.CCT.GTG.GAC.CGT.GC-3′) were used and the product was detected with oligomer hybridization with probe NC3 (5′-GGT.AGC.CAC.TAT.AGG. TGG.G-3′).

All samples were analyzed with the NS3-cDNA PCR in duplicate. Samples were considered positive when the duplicate tests were both reactive. Samples were considered negative if both duplicate tests were nonreactive. Results were considered indeterminate if one reactive and one nonreactive result was obtained. All negative and indeterminate samples were further analyzed with the 5′ UTR PCR on the reverse transcribed template in duplicate. Two NS-3 PCR indeterminate samples were considered HGV-RNA positive because the 5′ UTR PCR was reactive in duplicate.

E2 antibody test.

An experimental E2 enzyme-linked immunosorbent assay (ELISA; Abbott Diagnostics Division, Chicago, IL) was used as previously described.12 Purified GBV-C E2 was coated onto polystyrene beads. Plasma samples were diluted 1:300 and analyzed at Abbott Laboratories.

HCV cDNA PCR.

HCV-RNA detection was performed with an in house developed cDNA PCR assay.30 31 

ALT.

ALT values presented in this report were tested in the same serum samples as the samples used for PCR testing. Serum samples were tested for ALT by a standard automated method. Because for this method, the upper limit of normal varied with time, the results were expressed as an ALT index, calculated as the ALT level measured divided by the upper limit of normal. Hence an ALT index of <1 was considered to be normal.

Data Management and Statistical Analysis

Clinical and virological data were collected in separate data bases and were coupled after insuring anonymity. The study protocol was approved by the Medical Ethical Committee of the University Hospital Utrecht, the Netherlands.

For statistical analysis, the Fisher’s exact test and the χ2 Test for Trend were used.

HGV-RNA, HCV-RNA positivity, and E2 antibody reactivity in relation to age.

The prevalence of HGV-RNA was 18%. No difference was seen between patients with hemophilia A (46 of 252, 18%) and hemophilia B (8 of 34, 24%). Seven of 49 (14%) HGV-RNA positive patients and 74 of 120 (62%) HGV-RNA negative patients were E2 antibody reactive.

Table 1 shows the proportion of HGV-RNA and HCV-RNA positive patients in relation to age. The number of HGV-RNA positive patients was significantly higher in the group born between 1980 and 1989 than in the older age groups (P = .026), whereas the proportion of HCV-RNA positive patients was significantly lower in this particular group of relatively young patients (P < .0001). Two patients born after 1990 tested HGV-RNA positive.

Table 1.

Prevalence of HGV-RNA and HCV-RNA in Relation to Age

Year of Birth No. HGV-RNA Positive [95% CI]*HCV-RNA Positive [95% CI]
Before 1950  35 5-151 (14%) [5-30%] 27-152 (77%) [60-90%]  
1950-1959  52 6-151 (12%) [4-23%] 40-152 (77%) [63-87%]  
1960-1969  65 11-151 (17%) [9-28%] 49-152 (75%) [63-85%]  
1970-1979  68 11-151 (16%) [8-27%] 46-152 (68%) [55-78%]  
1980-1989  55 19-151 (35%) [22-49%] 13-152 (24%) [13-37%]  
1990-1993  19 2 (11%) [1-30%]  0 (0%) [0-18%] 
Total  294  54 (18%) [14-23%] 175 (60%) [54-65%] 
Year of Birth No. HGV-RNA Positive [95% CI]*HCV-RNA Positive [95% CI]
Before 1950  35 5-151 (14%) [5-30%] 27-152 (77%) [60-90%]  
1950-1959  52 6-151 (12%) [4-23%] 40-152 (77%) [63-87%]  
1960-1969  65 11-151 (17%) [9-28%] 49-152 (75%) [63-85%]  
1970-1979  68 11-151 (16%) [8-27%] 46-152 (68%) [55-78%]  
1980-1989  55 19-151 (35%) [22-49%] 13-152 (24%) [13-37%]  
1990-1993  19 2 (11%) [1-30%]  0 (0%) [0-18%] 
Total  294  54 (18%) [14-23%] 175 (60%) [54-65%] 

*95% CI = 95% confidence interval.

F0-151

Fisher’s Exact test 1980-1989 versus born before 1980, P = .026.

F0-152

Fisher’s Exact Test 1980-1989 versus born before 1980, P< .0001.

Table 2 shows the results of HGV-E2 antibody testing in patients with and without HGV viremia in relation to age. The prevalence of HGV-E2 antibodies increased with age. A total of 96% (CI, 80% to 100%) of patients born before 1950 tested positive.

Table 2.

Prevalence of E2 Antibody Reactivity in Relation to Age in Patients With and Without HGV Viremia

Year of Birth No. HGV-RNA Positive [95% CI]* HGV E2 ab Positive HGV-RNA Negative [95% CI] HGV E2 ab Positive
Before 1950  30  2/4 (50%) [7-93%] 25/26 (96%) [80-100%]  
1950-1959  30 0/6 (0%) [0-46%]  19/24 (79%) [58-93%]  
1960-1969 30  1/11 (9%) [0-41%]  14/19 (74%) [49-91%] 
1970-1979  30  3/10 (30%) [7-65%] 10/20 (50%) [27-73%]  
1980-1989  30 1/16 (6%) [0-30%]  6/14 (43%) [8-71%]  
1990-1993 19  0/2 (0%) [0-84%]  0/17 (0%) [0-19%]  
Total 169  7/49 (14%) [6-27%] 74/120 (62%) [52-70%] 
Year of Birth No. HGV-RNA Positive [95% CI]* HGV E2 ab Positive HGV-RNA Negative [95% CI] HGV E2 ab Positive
Before 1950  30  2/4 (50%) [7-93%] 25/26 (96%) [80-100%]  
1950-1959  30 0/6 (0%) [0-46%]  19/24 (79%) [58-93%]  
1960-1969 30  1/11 (9%) [0-41%]  14/19 (74%) [49-91%] 
1970-1979  30  3/10 (30%) [7-65%] 10/20 (50%) [27-73%]  
1980-1989  30 1/16 (6%) [0-30%]  6/14 (43%) [8-71%]  
1990-1993 19  0/2 (0%) [0-84%]  0/17 (0%) [0-19%]  
Total 169  7/49 (14%) [6-27%] 74/120 (62%) [52-70%] 

Abbreviation: ab, antibody.

*

95% CI = 95% confidence interval.

HCV-RNA and HGV-RNA positivity and HGV-E2 reactivity in relation to viral safety of clotting products.

Table 3 shows the results of HCV-RNA and HGV-RNA tests in relation to the clotting products used. Patients ever treated with nonviral inactivated plasma-derived clotting product (group A) had a higher prevalence of HCV viremia (71%) than HGV viremia (17%). However, in the group treated with suboptimal viral inactivated product (group B), a higher prevalence of HGV viremia was found (50%) as compared with HCV viremia (27%). No HCV infection was seen in patients exclusively treated with optimal viral inactivated or recombinant clotting factor concentrate (group C). In this group, two patients (6%) were HGV-RNA positive.

Table 3.

Prevalence of HGV-RNA and HCV-RNA in Relation to Viral Safety of the Clotting Products Used

Clotting Product Used No. HGV-RNA Positive [95% CI]*HCV-RNA Positive [95% CI]
Group A  
 Non- or suboptimal viral inactivated product  236   39 (17%)  [12-22%] 168 (71%)  [65-77%]  
Group B 
 Suboptimal and optimal viral inactivated product   26   13 (50%)  [30-70%]   7 (27%)  [12-48%]  
Group C 
 Optimal viral inactivated product, recombinant product  32     2 (6%)  [1-21%]   0 (0%)  [0-11%] 
Clotting Product Used No. HGV-RNA Positive [95% CI]*HCV-RNA Positive [95% CI]
Group A  
 Non- or suboptimal viral inactivated product  236   39 (17%)  [12-22%] 168 (71%)  [65-77%]  
Group B 
 Suboptimal and optimal viral inactivated product   26   13 (50%)  [30-70%]   7 (27%)  [12-48%]  
Group C 
 Optimal viral inactivated product, recombinant product  32     2 (6%)  [1-21%]   0 (0%)  [0-11%] 

*95% CI = 95% confidence interval.

Chi-squared test for Trend, not significant.

Chi-squared test for Trend, P < .00001.

A subgroup of 169 patients was tested for E2 antibodies. Of these patients, 120 were HGV-RNA negative, of whom 92 had in the past been treated with nonviral inactivated products. The majority of them, 70 of 92 (83%; CI, 66% to 84%), had been exposed to HGV as indicated by the presence of detectable E2 antibodies. In a small group of HGV-RNA negative patients who had been treated with suboptimal viral-inactivated products (group B) four of seven (57%; CI, 18% to 90%) were HGV anti-E2 positive, whereas none of 21 HGV-RNA negative patients exclusively treated with adequately inactivated product (group C) were anti-E2 positive (CI, 0% to 16%).

HGV-RNA and HCV-RNA in relation to ALT index.

In Table 4, the correlation between HGV-RNA and HCV-RNA status and the ALT index is shown. In HCV-RNA negative as well as HCV-RNA positive patients, the presence of HGV-RNA did not significantly influence the ALT index.

Table 4.

HGV-RNA Status in Relation to ALT Index and HCV-RNA Status

ALT Index3-150No. HGV/HCVHGV+/HCVHGV/HCV+HGV+/HCV+
<1  110  82 (74%)3-151 12 (11%)3-151 13 (12%)3-152 3 (3%)3-152 
1-2  89 16 (18%)  1 (1%)  55 (62%)  17 (19%)  
2-4 52  3 (6%)  —  37 (71%)  12 (23%) 
>4  38  2 (5%)  —  29 (76%) 7 (18%)  
Unknown  5  2   1  1   1  
ALT Index3-150No. HGV/HCVHGV+/HCVHGV/HCV+HGV+/HCV+
<1  110  82 (74%)3-151 12 (11%)3-151 13 (12%)3-152 3 (3%)3-152 
1-2  89 16 (18%)  1 (1%)  55 (62%)  17 (19%)  
2-4 52  3 (6%)  —  37 (71%)  12 (23%) 
>4  38  2 (5%)  —  29 (76%) 7 (18%)  
Unknown  5  2   1  1   1  

Abbreviation: NS, not significant.

F3-150

ALT index <1 is normal.

F3-151

Fisher’s Exact Test: ALT <1 versus ALT >1 P = .46 = NS.

F3-152

Fisher’s Exact Test: ALT <1 versus ALT >1 P = 1.00 = NS.

This study shows that 18% of our group of Dutch hemophilia patients is HGV-RNA positive. Fourteen percent HGV-RNA positive patients and 60% HGV-RNA negative patients were E2 antibody reactive. These results confirm the results of other studies showing that multitransfused hemophilia patients have often been exposed to HGV.14,21,23 24 

Intriguingly, patients born between 1980 to 1989 were significantly more often HGV-RNA positive (35%) than the patients in the older age groups (12% to 17%). By contrast, in HGV-RNA negative patients, the proportion of anti-E2 antibodies increased with age from 0% in patients born after 1990 to 96% in patients born before 1950. These findings might be explained by the fact that clearance of HGV may only occur after a long period of viremia.32 Hence, patients who were exposed to HGV after 1980 may not yet have completely recovered. This theory is supported by the findings of Tacke et al10and Dille et al12 who found that in patients with a posttransfusion hepatitis, the development of E2-specific HGV antibodies was associated with the loss of HGV viremia. Another possible explanation might be that patients born in the 1980s have more often initially been infected through intermediate or highly purified, non-, or suboptimal viral inactivated clotting factor concentrates. Plasma pools used for production of these concentrates might have been contaminated with a relatively high HGV load and through the purification process, the titer of neutralizing anti-E2 antibodies was reduced, but infectious viral particles persisted. Perhaps these patients have been at a higher risk of becoming chronic HGV carriers than have patients who were infected with less pure products, theoretically containing HGV complexed by neutralizing antibodies. Future follow-up studies on HGV-RNA and E2 antibody testing are needed to show the natural history of HGV infection in hemophilia patients and to exclude new infections. This is particularly important because it is still not clear whether the current optimally viral inactivated plasma-derived clotting products are HGV “safe.” HGV-RNA was found in various batches of plasma-derived clotting factor concentrate, which were optimal viral inactivated by dry heat treatment at 80°C for 72 hours or by pasteurization. Only products that were chemically viral inactivated by a solvent and detergent were HGV-RNA negative.14,16 Our study shows that the current methods of viral inactivation and the use of recombinant products strongly diminishes the evidence of HGV infection in recipients. In only two of 32 (6%) patients exclusively treated with this type of product was HGV viremia found, whereas none of the 23 patients tested was E2 antibody positive. By contrast, 52 of 262 (20%) of the patients ever treated with suboptimal or nonviral inactivated product were HGV viremic. We cannot exclude the possibility that the two young HGV-RNA positive patients were infected by the use of optimally viral inactivated (SD) plasma clotting factors, although vertical or intrafamiliar transmission, or infection through other routes, is also possible and needs to be studied. It is shown that vertical transmission of HGV is more common than in hepatitis C.18,19 Currently, no data are available on the prevalence of HGV-RNA and E2 antibodies in the population under the age of 18 years. From donor testing we know that the prevalence of HGV infection is higher than HCV.10,11 33 

The pathogenicity of HGV seems to be negligible. We did not find an increase of ALT levels in patients who were HGV-RNA positive and HCV-RNA negative. These results are in concordance with the studies published by Wang et al15 and Tanaka et al27who also found no signs of chronic liver disease in HGV carriers or a negative effect of a superinfection with HGV on the severity of HCV infection.

HGV infection is frequently seen in patients with hemophilia. This might be a result of the past use of non- or suboptimal virus inactivated plasma derived clotting factor concentrates. However, as age-matched control studies for comparison are missing, it is not clear how many infections are the result of the use of plasma-derived clotting factors, but current viral inactivation methods and recombinant products seem to reduce the risk of transmission significantly.

In older age groups, a lower rate HGV-RNA positivity is seen coinciding with a higher rate of antienvelope antibodies, suggesting the development of neutralizing antibodies.

In our study, we did not find a correlation between the ALT levels and HGV infection.

We are very grateful to Dr I.K. Mushawar (Abbott Diagnostics Division, North Chicago, IL) for performing the E2 envelope antibody ELISAs. We thank H. van Drimmelen for preparing part of the database.

Address reprint requests to Eveline P. Mauser-Bunschoten, MD, PhD, Van Creveldkliniek, Academisch Ziekenhuis Utrecht, Postbox 85500, 3508 AG Utrecht, The Netherlands; email: E.MauserBunschoten@digd.AZU.nl.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" is accordance with 18 U.S.C. section 1734 solely to indicate this fact.

1
Peterson
MR
Barker
MRLF
Schade
DS
Detection of antibody to hepatitis associated antigen in hemophilia patients and in voluntary blood donors.
Vox Sang
24
1973
66
2
Mauser-Bunschoten
EP
Bresters
D
van Drimmelen
AAJ
Roosendaal
G
Cuypers
HTM
Reesink
HW
van der Poel
CL
van den Berg
HM
Lelie
PN
Hepatitis C infection and viremia in Dutch hemophilia patients.
J Med Virol
45
1995
241
3
Wolfs
TFW
Breederveld
C
Krone
WJA
van den Hoek
L
Bakker
M
Smit
L
Goudsmit
J
the Dutch haemophilia group
HIV-antibody seroconversions in Dutch hemophiliacs using heat-treated and non heat-treated coagulation factor concentrates.
Thromb Haemost
59
1988
396
4
Morbidity and Mortality Weekly Report
Hepatitis A among persons with hemophilia who received clotting factor concentrate—United States, Sept-Dec 1995.
MMWR
42
1995
29
5
Grosse-Bley
A
Eis-Hübinger
AM
Kaiser
R
Oldenburg
J
Brackmann
HH
Schwarz
TF
Schneweis
KE
Serological and virological markers of human parvovirus B19 infection in sera of hemophiliacs.
Thromb Haemost
72
1994
503
6
Linnen
J
Wages
J
Jr
Zhang-Keck
ZY
Fry
KE
Krawczynski
KZ
Alter
H
Koonin
E
Gallagher
M
Alter
M
Hadziyannis
S
Karyiannis
P
Fung
K
Nakatsuji
Y
Shih
JW-K
Young
L
Piatak
M
Hoover
C
Fernandez
J
Chen
S
Zou
J-C
Morris
T
Hyams
KC
Ismay
S
Lifson
JD
Hess
G
Foung
SKH
Bradley
HTD
Margolis
H
Kim
JP
Molecular cloning and disease association of hepatitis G virus: A transfusion-transmissable agent.
Science
271
1996
505
7
Leary
TP
Muerhoff
AS
Simmons
JN
Pilot-Matias
TJ
Erker
JC
Chalmers
ML
Schlauder
GG
Dawson
GJ
Desai
SM
Mushawar
IK
Sequences and genomic organization of GBV-C: A novel member of the flaviviridae associated with human non-A-E hepatitis.
J Med Virol
48
1996
60
8
Muerhoff
AS
Leavy
TP
Simmons
JN
Pilot-Matias
TJ
Dawson
GJ
Erker
JC
Chalmers
ML
Schlauder
GG
Desai
SM
Mushawar
IK
Genomic organization of GB viruses A and B: Two new members of the flaviviridae associated with GB agent hepatitis.
J Virol
69
1995
5621
9
Yoshiba
M
Okamoto
H
Mashiro
S
Detection of the GBV-C hepatitis virus genome in serum from patients with fulminant hepatitis from unknown aetiology.
Lancet
346
1995
1131
10
Tacke
M
Kiyosawa
K
Strak
K
Schlueter
V
Ofenloch-Haehnle
B
Hess
G
Engel
AM
Detection of antibodies to a putative hepatitis G virus envelope protein.
Lancet
349
1997
318
11
Masuko
K
Mitsui
T
Iwano
K
Yamazaki
C
Okuda
K
Meguro
T
Murayama
N
Inoue
T
Tsuda
F
Okamoto
H
Miyakawa
Y
Mayumi
M
Infection with hepatitis GB virus C in patients on maintenance hemodialysis.
N Engl J Med
334
1996
1485
12
Dille
BJ
Surowy
TK
Gutierrez
RA
Coleman
PF
Knigg
MF
Carrick
RJ
Aach
RD
Hollinger
FB
Stevens
CE
Barbosa
LH
Nemo
GJ
Mosley
JW
Dawson
GJ
Mushahwar
IK
An ELISA for detection of antibodies to the E2 protein of GB virus C.
J Infect Dis
175
1997
458
13
Stark
K
Bienzie
U
Hess
G
Engel
AM
Hegenscheid
B
Schlüter
V
Detection of hepatitis G virus genome among injecting drug users, homosexual and bisexual men, and blood donors.
J Infect Dis
174
1996
1320
14
Jarvis
LM
Davidson
F
Hanley
JP
Yap
PL
Ludlam
CA
Simmonds
P
Infection with hepatitis G virus among recipients of plasma products.
Lancet
348
1996
1352
15
Wang
JT
Tsai
FC
Lee
CZ
Chen
PJ
Sheu
JC
Wang
TH
Chen
DS
A prospective study of transfusion-transmitted GB virus C infection: Similar frequency but different clinical presentation compared with hepatitis C virus.
Blood
88
1996
1881
16
Garcia-Trevijano
ER
López-Alcohorno
JM
Quintana
M
Hernández
F
Carreño
V
HGV in coagulation factor concentrates.
Lancet
348
1996
1032
17
Schreier
E
Höhne
M
Künkel
U
Berg
T
Hopf
U
Hepatitis GBV-C sequences in patients infected with HCV contaminated anti-D immunoglobulin and among i.v. drug users in Germany.
J Hepatol
25
1996
385
18
Feucht
HH
Zöllner
B
Polywka
S
Laufs
R
Vertical transmission of hepatitis G.
Lancet
347
1996
615
19
Zanetti
AR
Tanzi
E
Romanó
L
Principi
N
Zuin
G
Minola
E
Zapparoli
B
Palmieri
M
Marini
A
Ghisotti
D
Friedman
P
Hunt
J
Laffler T and the Lombardy Study Group on Vertical/Perinatal Hepatitis Virus Transmission
Multicenter trial on mother-to-infant transmission of GBV-C virus.
J Med Virol
54
1998
107
20
Roth
WK
Waschk
D
Marx
S
Tschauder
S
Zeuzem
S
Bialleck
H
Weber
H
Seifried
E
Prevalence of hepatitis G virus and its strain variant, the GB agent, in blood donations and their transmission recipients.
Transfusion
37
1997
651
21
Baker
R
Palladino
S
Kay
I
Lavis
N
Flexman
J
Low prevalence of hepatitis G in haemophilia patients in Australia.
Br J Haematol
96
1997
654
22
Sampietro
M
Corbetta
N
Cerino
M
Fabiani
P
Ticozzi
A
Orlandi
A
Lunghi
G
Fargion
S
Fiorelli
G
Cappellini
MD
Prevalence and clinical significance of hepatitis G infection in adult beta-thalassaemia major patients.
Br J Haematol
97
1997
904
23
Kinoshita
T
Miyake
K
Nakao
H
Tanaka
T
Tsuda
F
Okamoto
H
Miyakawa
Y
Mayumi
M
Molecular investigation of GB virus C infection in hemophiliacs in Japan.
J Infect Dis
175
1997
454
24
De Filippi
F
Colombo
M
Rumi
MG
Tradati
F
Prati
D
Zanella
A
Mannucci
PM
High rates of Hepatitis G virus infection in multitransfused patients with hemophilia.
Blood
90
1997
4634
25
Kao
J-H
Chen
P-J
Chen
D-S
GBV-C in the aetiology of fulminant hepatitis.
Lancet
347
1996
120
26
Tameda
Y
Kosaka
Y
Tagawa
S
Takase
K
Sawada
N
Nakao
H
Tsuda
F
Tanaka
T
Okamoto
H
Miyakawa
Y
Mayumi
M
Infection with GB virus C (GBV-C) in patients with fulminant hepatitis.
J Hepatol
25
1996
842
27
Tanaka
E
Alter
HJ
Nakatsuji
Y
Shih
W-K
Kim
JP
Matsumoto
A
Kobayashi
M
Kiyosawa
K
Effect of hepatitis G virus infection on chronic hepatitis C.
Ann Intern Med
125
1996
740
28
Bralet
MP
Roudot-Thoraval
F
Pawlotsky
J-M
Bastie
A
Tran van Nhieu
J
Duval
J
Dhumeaux
D
Zafrani
ES
Histopathologic impact of GB virus C infection on chronic hepatitis C.
Gastroenterology
112
1997
188
29
Martinot
M
Marcellin
P
Boyer
N
Detmer
J
Pouteau
M
Castelnau
C
Degott
C
Auperin
A
Collins
M
Kolberg
J
Wilber
J
Benhamou
J-P
Erlinger
S
Influence of Hepatitis G virus infection on the severity of liver disease and response to interferon-alpha in patients with chronic hepatitis C.
Ann Intern Med
126
1997
874
30
Cuypers
HTM
Bresters
D
Winkel
IN
Reesink
HW
Weinet
AJ
Houghton
M
Poel
van der C
Lelie
PN
Storage conditions of blood samples and primer selection affect the yield of cDNA-polymerase chain reaction products of hepatitis C virus.
J Clin Microbiol
30
1992
3220
31
Zaaijer
HL
Cuijpers
HTM
Reesink HW Winkel
IN
Gerken
G
Lelie
PN
Reliability of polymerase chain reaction for detection of hepatitis C virus.
Lancet
341
1993
722
32
Feucht
H-H
Zöllner
B
Polywka
S
Knödler
B
Schröter
M
Nolte
H
Laufs
R
Distribution of hepatitis G viremia and antibody response to recombinant proteins with special regard to risk factors in 709 patients.
Hepatology
26
1997
491
33
Poel van der CL
Reesink
HW
Mauser-Bunschoten
EP
Kaufman
RH
Leenvaart-Kuypers
A
Chamuleau
RAFM
Schaasberg
W
Bakker
E
Exel-Oehlers
PJ
Theobalds
I
Boven van JJP
Cameron
A
Lelie
PN
Prevalence of anti-HCV antibodies confirmed by recombinant immunoblot in different population subsets in The Netherlands.
Vox Sang
61
1991
30
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