Jean-Pierre Allain

STATEMENTS FROM THE TAORMINA EXPERT MEETING ON OCCULT HEPATITIS B VIRUS INFECTION

Giovanni Raimondo*, Jean-Pierre Allain, Maurizia R. Brunetto, Marie-Annick Buendia, Ding-Shinn Chen, Massimo Colombo, Antonio Craxi, Francesco Donato, Carlo Ferrari, Giovanni B. Gaeta, Wolfram H. Gerlich, Massimo Levrero, Stephen Locarnini, Thomas Michalak, Mario U. Mondelli, Jean-Michel Pawlotsky, Teresa Pollicino, Daniele Prati, Massimo Puoti, Didier Samuel, Daniel Shouval, Antonina Smedile, Giovanni Squadrito, Christian Trepo, Erica Villa, Hans Will, Alessandro R. Zanetti, Fabien Zoulim

Occult hepatitis B virus infection: implications in transfusion.

Hepatitis B virus (HBV) presents a higher residual risk of transmission by transfusion than hepatitis C virus (HCV) or human immunodeficiency virus (HIV). While most infectious blood units are removed by screening for hepatitis B surface antigen (HBsAg), there is clear evidence that transmission by HBsAg‐negative components occurs, in part, during the serologically negative window period, but more so during the late stages of infection. Donations negative for HBsAg, but positive for HBV DNA, with or without the presence of HBV antibodies, correspond to ‘occult’ HBV infection (OBI). The frequency of OBI depends on the relative sensitivity of both HBsAg and HBV DNA assays. It also depends on the prevalence of HBV infection in the population. OBI may follow recovery from infection, displaying antibody to hepatitis B surface antigen (anti‐HBs) and persistent low‐level viraemia, escape mutants undetected by the HBsAg assays, or healthy carriage with antibodies to hepatitis B e antigen (anti‐HBe) and to hepatitis B core antigen (anti‐HBc). Over time, in the latter situation, anti‐HBe and, later, anti‐HBc may become undetectable. The critical question is whether or not OBI is infectious by transfusion. All forms have been shown to be infectious in immunocompromised individuals, such as organ‐ or bone marrow‐transplant recipients. In immunocompetent recipients, there is no evidence that anti‐HBs‐containing components (even at low titre) are infectious. Anti‐HBc only, with HBV DNA, can be associated with infectivity, as can rare cases of HBV DNA without any serological HBV marker. If HBV nucleic acid amplification technology (NAT) is considered, the OBI viral load would usually be < 500 IU/ml, making testing of plasma pools unsuitable unless the sensitivity of NAT significantly increases by genome enrichment or test improvement.

SEROLOGICAL MARKERS IN EARLY STAGES OF HUMAN IMMUNODEFICIENCY VIRUS INFECTION IN HAEMOPHILIACS

Immunoassays for human immunodeficiency virus antigen (HIV Ag) and for antibody to HIV core and envelope (CIA-RA) were done on serial specimens from 40 haemophiliacs who had become seropositive on screening by enzyme-linked immunosorbent assay (ELISA). HIV Ag was detectable in 9 subjects and antibodies to envelope in 11 subjects before ELISA seroconversion. The apparent sequence of markers is HIV Ag, antibody to envelope, then antibody to core. Antigenaemia could be detected as soon as 2 weeks after infection and lasted 3-5 months. 82% agreement was seen between CIA-RA and western blot; CIA was more sensitive to envelope antibody and western blot was more sensitive to core antibody.

Nucleic Acid Testing to Detect HBV Infection in Blood Donors

BACKGROUND The detection of hepatitis B virus (HBV) in blood donors is achieved by screening for hepatitis B surface antigen (HBsAg) and for antibodies against hepatitis B core antigen (anti-HBc). However, donors who are positive for HBV DNA are currently not identified during the window period before seroconversion. The current use of nucleic acid testing for detection of the human immunodeficiency virus (HIV) and hepatitis C virus (HCV) RNA and HBV DNA in a single triplex assay may provide additional safety. METHODS We performed nucleic acid testing on 3.7 million blood donations and further evaluated those that were HBV DNA-positive but negative for HBsAg and anti-HBc. We determined the serologic, biochemical, and molecular features of samples that were found to contain only HBV DNA and performed similar analyses of follow-up samples and samples from sexual partners of infected donors. Seronegative HIV and HCV-positive donors were also studied. RESULTS We identified 9 donors who were positive for HBV DNA (1 in 410,540 donations), including 6 samples from donors who had received the HBV vaccine, in whom subclinical infection had developed and resolved. Of the HBV DNA-positive donors, 4 probably acquired HBV infection from a chronically infected sexual partner. Clinically significant liver injury developed in 2 unvaccinated donors. In 5 of the 6 vaccinated donors, a non-A genotype was identified as the dominant strain, whereas subgenotype A2 (represented in the HBV vaccine) was the dominant strain in unvaccinated donors. Of 75 reactive nucleic acid test results identified in seronegative blood donations, 26 (9 HBV, 15 HCV, and 2 HIV) were confirmed as positive. CONCLUSIONS Triplex nucleic acid testing detected potentially infectious HBV, along with HIV and HCV, during the window period before seroconversion. HBV vaccination appeared to be protective, with a breakthrough subclinical infection occurring with non-A2 HBV subgenotypes and causing clinically inconsequential outcomes. (Funded by the American Red Cross and others.).

Long-term evaluation of HIV antigen and antibodies to p24 and gp41 in patients with hemophilia. Potential clinical importance

To investigate the relation between human immunodeficiency virus (HIV) antigenemia and clinical manifestations of HIV infections, we studied 96 patients with hemophilia who were positive for HIV antibody, for a median of 34 months. Every 4 to 10 months a clinical and laboratory examination was performed and serum samples were tested for three HIV markers: HIV antigen, antibody to p24, and antibody to gp41. Twenty-two subjects (23 percent) were found to be positive for HIV antigen: 8 were positive upon entry and remained so (Group 1), and 14 became positive during the study, 4 to 26 months after HIV antibody appeared (seroconversion), 13 of whom remained positive for HIV antigen (Group 2). Most subjects positive for HIV antigen had low or undetectable titers of antibody to p24, whereas the antibody titer to gp41 remained high. In Group 2, patients with low p24 antibody titers had further decreases in their titers before or at the time HIV antigen appeared. Once present, HIV antigen persisted and tended to increase in concentration. In contrast to Group 3 (negative for HIV antigen, low anti-p24 titer) and 4 (negative for HIV antigen, high anti-p24 titer), the groups positive for HIV antigen had significantly higher incidences of acquired immunodeficiency syndrome (P = 0.05), immunodeficiency-related infections (P less than 0.001), and immune thrombocytopenia (P = 0.001), and had more severe disease as measured by the Walter Reed staging system (P less than 0.001). In this study, HIV antigen appeared to be a better predictive marker of HIV-related complications than the absolute T4+ count. These results suggest that HIV antigenemia indicates a poor clinical prognosis.

Identification and characterization of persistent human erythrovirus infection in blood donor samples.

ABSTRACT The presence of human erythrovirus DNA in 2,440 blood donations from the United Kingdom and sub-Saharan Africa (Ghana, Malawi, and South Africa) was screened. Sensitive qualitative and real-time quantitative PCR assays revealed a higher prevalence of persistent infection with the simultaneous presence of immunoglobulin G (IgG) and viral DNA (0.55 to 1.3%) than previously reported. This condition was characterized by a low viral load (median, 558 IU/ml; range, 42 to 135,000 IU/ml), antibody-complexed virus, free specific IgG, and potentially infectious free virus. Human erythrovirus genotype 1 (formerly parvovirus B19) was prevalent in the United Kingdom, Malawi, and South Africa. In contrast, only human erythrovirus genotype 3 (erythrovirus variant V9) was prevalent in Ghana. Genotype 3 had considerable genetic diversity, clustering in two probable subtypes. Genotype 1-based antibody assays failed to detect 38.5% of Ghanaian samples containing antibodies to genotype 3 virus but did not fail to detect cases of persistent infection. This study indicates a potential African origin of genotype 3 human erythrovirus and considerable shortcomings in the tools currently used to diagnose erythrovirus infection.

The global spread of hepatitis C virus 1a and 1b: a phylodynamic and phylogeographic analysis.

Using phylodynamic and phylogeographic methods, Angelos Hatzakis and colleagues find that the global spread of Hepatitis C virus coincided with widespread use of transfused blood and with the expansion of intravenous drug use.

Predonation screening of blood donors with rapid tests: implementation and efficacy of a novel approach to blood safety in resource-poor settings.

BACKGROUND:  In sub‐Saharan Africa, the percentage of screened blood is limited to approximately 75 percent for human immunodeficiency virus antibodies (anti‐HIV), 50 percent for hepatitis B surface antigen, and 19 percent for hepatitis C virus antibodies (anti‐HCV), mainly because of costs.

Transfusion-transmitted infectious diseases

A spectrum of blood-borne infectious agents is transmitted through transfusion of infected blood donated by apparently healthy and asymptomatic blood donors. The diversity of infectious agents includes hepatitis B virus (HBV), hepatitis C virus (HCV), human immunodeficiency viruses (HIV-1/2), human T-cell lymphotropic viruses (HTLV-I/II), Cytomegalovirus (CMV), Parvovirus B19, West Nile Virus (WNV), Dengue virus, trypanosomiasis, malaria, and variant CJD. Several strategies are implemented to reduce the risk of transmitting these infectious agents by donor exclusion for clinical history of risk factors, screening for the serological markers of infections, and nucleic acid testing (NAT) by viral gene amplification for direct and sensitive detection of the known infectious agents. Consequently, transfusions are safer now than ever before and we have learnt how to mitigate risks of emerging infectious diseases such as West Nile, Chikungunya, and Dengue viruses.

Protecting the Blood Supply From Emerging Pathogens: The Role of Pathogen Inactivation

Although the risk of infection by blood transfusion is relatively low, breakthrough infections still occur, Transfusion-related fatalities caused by infections continue to be reported, and blood is not tested for many potentially dangerous pathogens. The current paradigm for increasing the safety of the blood supply is the development and implementation of laboratory screening methods and restrictive donor criteria. When considering the large number of known pathogens and the fact that pathogens continue to emerge, it is clear that the utility of new tests and donor restrictions will continue to be a challenge when considering the cost of developing and implementing new screening assays, the loss of potential donors, and the risk of testing errors. Despite improving the safety of blood components, testing remains a reactive approach to blood safety. The contaminating organisms must be identified before sensitive tests can be developed. In contrast, pathogen inactivation is a proactive strategy designed to inactivate a pathogen before it enters the blood supply. Almost all pathogen inactivation technologies target nucleic acids, allowing for the inactivation of a variety of nucleic acid–containing pathogens within plasma, platelets, or red blood cells thus providing the potential to reduce transfusion-transmitted diseases. However, widespread use of a pathogen inactivation technology can only be realized when proven safe and efficacious and not cost-prohibitive.