Hepatitis B ; genetics ; virology ; Hepatitis B virus ; genetics

Hepatitis B virus ; Hepatitis B, Chronic ; genetics ; Humans ; Transcription, Genetic

OBJECTIVE: To understand the infection of hepatitis B virus(HBV) in blood donors, and to evaluate the effectiveness and necessity of TMA technology for HBV-DNA screening in blood donors. METHODS: Using the ELISA/NAT model, routine serology test and NAT were performed in the 169 160 donors，including voluntary blood donors and some of donors returned to donor team. For some donors with test positive NAT, nucleic acid identification test was performed. And the HBsAg neutralized and confirmed assay would conduct in blood donors with unilateral HBsAg positive and HBV-DNA negative result. RESULTS: Among 169 160 donation cases-times, the donors of bilateral positive of HBsAg detection was 803, accounted for 0.476%; donors of unilateral positive was 243, accounted for 0.144%. For 40 specimens with HBV-DNA negative, unilateral HBsAg positive, the neutralization and confirmed assay was performed.In result, only 4 specimens were confirmed to be HBsAg positive, the confirmed positive rate was 10%. Among detected 1003 specimens with HBV-DNA positive specimens, both HBsAg and HBV-DNA positive were 739, the consistency rate between 2 kinds of detection was 73.7%. The comparision of positive rate detected by using 3 kinds of reagents showed that there were statistical differences (P＜0.05); moreover, there were statistical difference in positive rate detected by using Murex reagent and In Tec reagent (P＜0.0125). The comparison of detected rate of HBsAg and HBV-DNA during March 2016-February 2017 showed no statistical difference (P＞0.05). Among 60 blood donors with HBsAg and HBV-DNA who has retured to the donor team, 1 donor presented the transformation of HBsAg from negative to positive, suggesting the HBV infection of window period, HBsAg of the other 59 was negative. The detection of HBV-DNA showed that the HBV-DNA in 28 donors was negative, and the HBV-DNA in 31 donors was positive, 1 donor showed HBV-DNA was uncertain. CONCLUSION The routine TMA technology combined with ELISA HBsAg can effectively shorten the window period for detection of HBV infection, effectively detect the occult HBV infection, and reduce the potential risk of hepatitis B spread due to blood transfusion.
Blood Donors ; DNA, Viral ; Hepatitis B ; Hepatitis B Surface Antigens ; Hepatitis B virus ; genetics ; Humans

OBJECTIVE: To evaluate the risk of reentry in HBV reactive blood donors and feasibility of HBV reentry strategy. METHODS: HBsAg⁺ or HBV DNA⁺ donors who had been quarantined for more than 6 months in Jiangsu Province could propose for reentry application. Blood samples were routinely screened by dual-ELISA for HBsAg, anti-HCV, HIV Ab/Ag, and anti- Treponema pallidum and those non-reactive ones were tested by minipool nucleic acid testing (NAT) for three times. To identify occult HBV donors, samples of NAT non-reactive were further tested by electrochemiluminescence immunoassay (ECLIA) for HBV seromarkers (including HBsAg, HBsAb, HBeAg, HBeAb, and HBcAb). Donors of only 4 ECLIA patterns were accepted to reentry, including all 5 HBV seromarkers negative, anti-HBs only but having history of hepatitis B vaccine injection, HBcAb only, HBsAb⁺ / HBcAb⁺ with HBsAb more than 200 IU/L. Additionally, the detection rate of HBV infection was compared between routine screening mode and ECLIA, as well as the reentry qualified rate of HBsAg⁺ and HBV DNA⁺ blood donors. RESULTS: From Oct. 2016 to Aug. 2019, a total of 737 HBV reactive donors had applied for reentry, including 667 HBsAg⁺ reactive and 70 HBV DNA⁺ reactive donors. Among 3 screening methods, the highest HBV detection rate (43.15%, 318/737) was observed on ECLIA, while only 4.75% (35/737) on ELISA and 3.12% (23/737) on NAT, respectively. Among 4 qualified patterns of HBV serological markers, the highest proportion was found in the all negative group (22.90%, 155/677), followed by the group with HBsAb⁺ only and history of hepatitis B vaccine injection (19.35%, 131/677), and the median concentration of HBsAb was 237.7 IU/L. The unqualified rate of HBV DNA⁺ donors was 82.86%, which was significantly higher than 47.98% of HBsAg⁺ donors. CONCLUSION Routine screening tests merely based on ELISA and NAT could miss occult HBV donors and may not be sufficient for blood safety. HBsAb concentration and vaccine injection history should be included in the evaluation of HBV reactive donors who intend to apply for reentry. There is a relatively larger residual risk of occult HBV infection in blood donors quarantined for HBV DNA reactive.
Blood Donors ; DNA, Viral ; Hepatitis B ; Hepatitis B Surface Antigens ; Hepatitis B virus/genetics* ; Humans

Critical Illness ; Hepatitis B virus ; genetics ; physiology ; Hepatitis B, Chronic ; virology ; Humans ; Transcription, Genetic ; Virus Replication

Alanine Transaminase ; Hepatitis B ; Hepatitis B e Antigens ; Hepatitis B virus/genetics* ; Hepatitis B, Chronic/drug therapy* ; Humans

Severe hepatitis B is an infectious disease which has high case fatality rate and is seriously harmful to human health. Its pathogenesis is complicated. In this article are reviewed the research reports on the virus and the host factors in the course of severe hepatitis B in recent years, including the advancement of researches on viral genotypes, viral mutations, immune responses and cytokines. These data are available for exploring the pathogenesis and for developing the clinical treatment of severe hepatitis B in future.
Animals ; Cytokines ; genetics ; Hepatitis B ; genetics ; immunology ; pathology ; Hepatitis B virus ; genetics ; Humans ; Mutation

Cloning, Molecular ; DNA, Viral ; genetics ; Genome, Viral ; genetics ; Hepatitis B ; virology ; Hepatitis B virus ; genetics ; Humans

<b>OBJECTIVEb>To evaluate the replication and encapsidation of HBV mutants with the truncated C gene.

<b>METHODSb>The HBV mutants with the truncated C gene were constructed by molecular cloning and PCR-based deletion in vitro. The replication and encapsidation of HBV mutants were investigated by Southern blotting, PCR and real-time fluorescence PCR respectively after transfecting the HBV mutants plasmid into HepG2 cells by using liposome.

<b>RESULTSb>The C-truncated HBV mutant vectors were constructed successfully and confirmed exactly by clone sequencing and enzymes digestion. The C-truncated HBV mutants were replication defective, however, all types of HBV DNA could be detected positive in the cytoplasm and supernatant after co-transfecting the C-truncated HBV mutants plasmid and the helper constructs into HepG2 cells. The C-truncated HBV mutants were proved to produce 3-40 folds more progeny DNA than that of the wild-type HBV by DNA quantitative assay.

<b>CONCLUSIONb>The C-truncated HBV mutants are replication-deficient and could not replicate and encapsulate in the hepatocytes when transfected solely, however, the progeny HBV-variant viruses are encapsidated more effectively to secrete into supernatant when co-transfected with the helper construct which lacks part of 5 prime-proximal HBV RNA packaging signal Epsilon.

Cell Line, Tumor ; Hepatitis B Core Antigens ; genetics ; Hepatitis B virus ; genetics ; physiology ; Humans ; Mutation ; Plasmids ; genetics ; Transfection ; Virus Replication

Hepatitis B virus (HBV) infection is one of the most serious public health problems. HBV infection could lead to hepatitis B, and even further develop into hepatic cirrhosis and hepatocellular carcinoma. Interferon lambda (IFN-λ) is a member of the interferon (IFN) family and an important cytokine for antiviral defense. There are four members in IFN-λ family, including IFN-λ1, IFN-λ2, IFN-λ3, and IFN-λ4. The genetic polymorphisms in the IFN-λ genes are associated with HBV replication and treatment response of HBV patients. In this review, we summarized the roles of genetic polymorphisms of the IFN-λ genes played in HBV infection, disease progression and treatment, with the aim to better understand their function. This review could serve as a reference for the HBV prevention and treatment of HBV patients, as well as for future clinical usage.
Antiviral Agents/pharmacology* ; Hepatitis B/genetics* ; Hepatitis B virus/genetics* ; Humans ; Interferons/pharmacology* ; Liver Neoplasms ; Polymorphism, Genetic ; Virus Replication/genetics*