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Clinical Trial Summary

Background and aims: Nucleos(t)ide analogues may suppress HBV DNA to undetectable level, but only about 30-40% remain sustained response 1-3 years after discontinued therapy. The investigators will try to improve the sustained response rate by given a course of HBV vaccination during the last 6 months on patients receiving a 3-year entecavir or tenofovir therapy.

Rational: The host may response to HBV vaccine when HBV DNA and immune tolerance are suppressed during entecavir or tenofovir therapy.

Patients: Patients who have been receiving entecavir or tenofovir therapy for at least 30 months will be invited to this study. The case group will receive 5 Engerix-B injections during the last 6 months of entecavir or tenofovir therapy. Arm A-entecavir pretreated group: 75 cases will be enrolled to receive Engerix-B injection and compared with histological non-vaccine treated controls; Arm B-tenofovir pretreated group: 50 patients will be randomized into case (vaccine) and control group according to age, gender, pretreatment HBV DNA level.

Therapy: Both case and control groups will receive a 3 year or longer entecavir or tenofovir therapy. Patients will be screen at 24-30 months and enrolled at 30 months after entecavir or tenofovir therapy. They will receive 5 Engerix-B injections at 0,1st ,2nd,3rd and 6th month [30-36 +/-1 month post nucleos(t)ide therapy] post enrollment. Both drugs will be discontinued after completed therapy.

Follow-up: Both groups will be monitoring by biochemistry, alpha-fetoprotein, quantitative HBsAg, HBV DNA levels and immunological parameter periodically for 2 years after therapy.

Efficacy: Those patients with persistent normal ALT and HBV DNA lower than 1*100000 cps/mL after discontinued nucleos(t)ide analogues therapy will be considered to have sustained response. Patients with transient elevation of HBV DNA and ALT, but normalized spontaneously without further therapy will be defined as delayed response. Patients with persistent HBV DNA greater than 1*100000 cps/mL will be considered to have non-sustained response.

Study duration: The enrollment will be completed in one year and keep on observation for additional 2 years.

Expected goals of the study: HBV vaccine and nucleos(t)ide analogues combination therapy may decrease the HBV relapse rate at 1 and 2 year after completed therapy.


Clinical Trial Description

Introduction Chronic hepatitis B virus (HBV) infection is a widely prevalent global health problem with estimate 350-400 million chronic HBV carriers worldwide. In China, Southeast Asia and sub-Saharan Africa, as many as 10-15% of the population are chronically infected with HBV. In North America and North Europe, HBV chronic carrier rates are much lower, usually below 1%. Intermediate HBV carrier rates of 1-7% are found in parts of Southern and Eastern Europe, Central America, the Middle East and parts of Japan (1-4).

HBV is highly infectious; many chronic HBsAg carriers were infected in their family shortly after birth or in early childhood (5-7). Recent genome-wide association studies revealed antigen presenting molecules, Human leukocyte antigen-DP (HLA-DP) and HLA-DQ, are associated with persistence HBV infection (8-10). HBV is actively replicated in chronic carriers during the initial immune tolerance phase (11). Impaired innate and adaptive immune responses to HBV can be found during this stage (12-16). They are generally asymptomatic until the immune clearance phase developed. At this stage, innate immunity, HBV-specific and non-specific T cells and other immune cells may orchestra an immune response and hepatic necroinflammation to clear HBV (17-19). The immune clearance phase is critical to the outcome of chronic HBsAg carriers. Those patients with prolonged HBV replication and repeated hepatic inflammation will run into liver cirrhosis and /or hepatocellular carcinoma (HCC) (20-23). How to terminate HBV replication is an important issue in management of chronic HBsAg carriers.

1.1 Therapy for chronic hepatitis B In the past 20 years, significant improvements in treatment of chronic hepatitis B (CHB) have been achieved by introducing regimen of interferon derivatives and nucleotide/nucleoside analogues (NA) (24-26). Interferon is a T helper cell type 1 cytokine that promotes immunity of host to clear HBV (27,28). NA inhibit HBV DNA synthesis by termination the nascent proviral DNA chain. About 30% patients may have complete response with normalization alanine aminotransferase (ALT) and HBV DNA lower than 10000 cps/mL one to three year after discontinued therapy (10,29-31). For the rest of patients a flare-up HBV replication occurred (10,29-31), a life-long therapy may be needed to eliminate covalently closed circular DNA (cccDNA) pool and achieved a sustained therapeutic response (32). Unfortunately, the prolonged use of NA need a lot of budgets and carried a substantial risk for emerging drug resistance mutants (33). The interferon derivatives regimens have similar efficacy with significant side effects (27,28). Therefore, Development of a safe and affordable anti-HBV agent/strategy is needed to further improve outcomes (34).

1.2 Rational for combine HBV vaccine with NA therapy NA therapy may suppress Serum HBV DNA to undetectable level (29-31). These drugs are acceptable to most of the patients because they are admitted orally, once daily and without significant side effect. The main problem is HBV DNA tends to relapse in approximately 70% of patients 1-3 years after discontinued therapy (10, 29-31).

When HBV was suppressed by NA therapy, the immune tolerance may also be suppressed. The post treatment relapse is an indirect evidence of losing immune tolerance in such patients (29-31). The post treatment clinical relapse is associated with enhanced Th1 response (35-37). T regulatory (Treg) cells, macrophages and other unidentified factors may play important roles on HBV tolerance (19, 38-41). One of an important phenomenon for patients receiving NA therapy is decrease of Treg cells level (42,43). The post treatment relapse of hepatic necroinflammation is an evidence of the restored HBV specific immune response (44,45).

In addition to the relief of immune tolerance, NA may suppress the HBsAg production from free virus, but no effect is expected for those HBsAg produced by integrated HBV genome. These two types of HBsAg may have some differences on protein conformation and behavior (46,47). The vaccine is produced according to free virus. Therefore, when the HBsAg produced by free virus is suppressed by NA to a low level, the vaccine may be recognized as a new antigen. The immune response elicited by the therapeutic vaccine may have a potential on suppression of free virus.

1.3 Combined HBV vaccine and NA therapy in animal study A Woodchuck animal study suggest entecavir therapy followed by Woodchuck surface (WHs) and core (WHc) DNA vaccination 7 weeks later may induce WHc and WHs specific T cell responses. Two of the 6 animals clear Woodchuck surface antigen (WHBsAg) and product anti-WHBs (48). Similar results can be found in HBV transgenic mice model. Hepatitis B surface (HBs) and hepatitis B core (HBc) specific cellular and humoral response was identified after HBc and HBs protein vaccine therapy (49). In a mouse model with sustained HBV viremia after infection with a recombinant adeno-associated virus carrying a replicable HBV genome. Immunization with the conventional HBV vaccine in the presence of aluminum adjuvant failed to elicit an immune response,but vaccination of mice with HBsAg/CpG induced strong antibody production and T-cell responses(50)

1.4 Combined HBV vaccine and NA therapy in liver transplantation Prevention of HBV reinfection is an important issue in chronic hepatitis B received liver transplantation. HBsAg immunoglobulin (HBIG) is the choice of therapy with evident of good protection (51). However, HBIG is quite expensive and long term therapy is needed. Combination of HBV vaccine and NA therapy had been done in patients received liver transplantation. The initial reports were not good (52-54), but recent studies suggest up to 50% patients response to lamivudine and HBV vaccination combination therapy (55,56) after adjusted dose of HBIG. All these studies did not report severe adverse event using lamivudine and HBV vaccine combination therapy.

1.5 Combined HBV vaccine and NA therapy in patients with chronic hepatitis B To increase response rate many HBV vaccines has been developed by increase immune epitope or posttranslation modifications (57,58) Combination of Lamivudine with therapeutic HBsAg DNA vaccination led to the persistence of T-cell responses (59). An HBV therapeutic vaccine clinical trial studies showed a decrease of HBV replication in hepatitis B e antigen (HBeAg) positive patients received HBV vaccine and lamivudine combination therapy (60).

2. Study objectives To understand the efficacy of combining a 3-year NA and Engerix-B therapy in sustained viral suppression.

3. Investigational plan 3.1 Overall study design This trials will examine the efficacy of NA and Engerix-B combination therapy in chronic hepatitis B.

3.2 Study design Arm A-entecavir pretreated group: Case vs. histological control study. Arm B-tenofovir pretreated group: randomized case and control study. 3.3. Therapy 3.3.1 Entecavir 0.5 mg daily for at least 3 years. 3.3.2 Tenofovir 300 mg daily for at least 3 years. 3.3.3 Five doses of Engerix-B 20 ug during the last 6 month of NA therapy in case group.

Both case and control groups will complete a 3-year NA therapy. The vaccination group will receive a course of Engerix-B vaccination. They will be enrolled at the last 6 months of the NA therapy. Engerix-B will be given at the 0,1st ,2nd 3rd and 6th month after the enrollment. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT02505009
Study type Interventional
Source Chang Gung Memorial Hospital
Contact
Status Completed
Phase Phase 4
Start date May 1, 2015
Completion date December 21, 2018

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