Comparison of clinical practice guidelines for the management of chronic hepatitis B: When to start, when to change, and when to stop
Article information
Abstract
Clinical practice guidelines are important for guiding the management of specific diseases by medical practitioners, trainees, and nurses. In some cases, the guidelines are utilized as a reference for health policymakers in controlling diseases with a large public impact. With this in mind, practice guidelines for the management of chronic hepatitis B (CHB) have been developed in the United States, Europe, and Asian-Pacific regions to suggest the best-fit recommendations for each social and medical circumstance. Recently, the Korean Association for the Study of the Liver published a revised version of its clinical practice guidelines for the management of CHB. The guidelines included updated information based on newly available antiviral agents, the most recent opinion on the initiation and cessation of treatment, and updates for the management of drug resistance, partial virological response, and side effects. Additionally, CHB management in specific situations was comprehensively revised. This review compares the similarities and differences among the various practice guidelines to identify unmet needs and improve future recommendations.
INTRODUCTION
Chronic hepatitis B virus (HBV) infection is a global health problem [1]. Although several therapeutic agents have been approved and used for patients with HBV infection, the disease remains difficult to cure, and the eradication of chronic infections remains challenging [2-5]. Current clinical practice guidelines or guidance by the American Association for the Study of Liver Diseases (AASLD) [6], European Association for the Study of the Liver (EASL) [7], and Asian-Pacific Association for the Study of the Liver (APASL) provides general recommendations for the management of chronic hepatitis B (CHB) (Table 1) [8]. Recently, in 2019, the Korean Association for the Study of the Liver (KASL) published new clinical practice guidelines for the management of CHB in this journal and described comprehensive management strategies including prevention, monitoring, treatment, and special considerations [9]. Here, we compare the Korean guidelines with other international guidelines regarding when to start, when to change, and when to stop antiviral treatment for CHB.
NATURAL HISTORY
CHB is a life-long disease that can start at the beginning of life by perinatal transmission, especially in Asian countries [3]. Five characteristic phases of CHB have been identified according to immunological features, virology, biochemistry, and histology (Table 2) [3].
The first phase is the CHB immune tolerant phase (immune tolerant CHB). It is characterized by very high levels of HBV replication, persistently normal alanine aminotransferase (ALT) levels, and minimal or no necroinflammatory activity. During this phase, patients are typically positive and show high titers of hepatitis B surface antigen (HBsAg) and hepatitis B e antigen (HBeAg). Inflammatory activity is assumed to be absent, which prompted the EASL to revise the name of the first phase to HBeAg-positive chronic HBV infection [7]. However, normal ALT levels do not exclude the presence of necroinflammation and fibrosis, particularly as determined by conventional laboratory criteria [10,11]. Therefore, the KASL adjusted the cut-off of normal ALT to 34 IU/L for males and 30 IU/mL for females on the basis of a recent study involving 12,486 Korean CHB patients [9,12]. Experts from the AASLD recommended the use of similar cut-offs of 35 IU/L for males and 25 IU/mL for females, whereas the EASL and APASL insist on using traditional laboratory reference values of 40 IU/mL for both sexes (Table 1) [6]. Another issue differentiating the immune tolerant phase from other phases is the cut-off of the very high HBV DNA levels. The HBV DNA criterion (≥107 IU/mL) for the immune tolerant phase as defined by the KASL and EASL is somewhat different from that of the AASLD (>106 IU/mL) and the APASL (>2×106 IU/mL) [6-9]. However, given that a decreasing HBV DNA titer suggests immunological interactions between the host and virus, a higher cut-off would be suitable to exclude patients in transition phases who may need antiviral treatment [13]. Indeed, the definition of the immune tolerant phase is still under debate [13,14], causing investigators to continue evaluating the appropriate cut-offs of the ALT and HBV DNA levels for the accurate prediction of long-term prognosis and recommendation of suitable treatment.
The second phase is the HBeAg-positive immune active phase. This is also termed the immune reactive or immune clearance phase [3]. The level of HBV DNA remains high (104 –107 IU/mL according to the EASL) but may fluctuate [3]. Elevated ALT suggests the presence of intrahepatic necroinflammation and can be associated with liver damage [15]. The outcome of this phase varies according to the degree of liver injury; thus, prompt antiviral therapy is recommended [15].
The third phase is the immune inactive phase, previously known as the immune controlled phase [3]. Other terminologies for this phase include HBeAg-negative chronic HBV infection, as proposed by the EASL, and low replicative chronic HBV infection or low replicative phase, as proposed by the APASL [7,8], emphasizing the minimal intrahepatic inflammation and low viral replication. The level of HBV DNA is typically as low as <2,000 IU/mL, and the ALT level is within the upper limit of the normal (ULN) range. If patients remain in this phase, prognosis is favorable, and the HBsAg levels may decrease at 1–3% per year. However, low level persistent viremia can be associated with live disease progression, and a number of patients transit to the HBeAg-negative immune-active phase of CHB annually [16].
The fourth phase is the HBeAg-negative CHB immune active phase, which was previously known as the immune escape phase or reactivation phase [3,17]. The moderate to high levels of HBV replication (>2,000 IU/mL) and negative HBeAg status in this phase are caused by mutations on the pre-core or core promoter regions of HBV DNA, blocking HBeAg production [18,19]. The prolonged viral replication and intrahepatic necroinflammation observed during this phase are associated with progression to liver cirrhosis or the development of hepatocellular carcinoma (HCC) [3,20].
The last phase is the HBsAg loss phase, in which HBsAg is spontaneously cleared [21]. Although the incidence of HBsAg loss is very low (<0.5% per year), the risk of disease progression substantially decreases [21,22]. However, HCC surveillance should be continued if HBsAg loss occurs after age ≥50 years as recommended by the KASL. The AASLD suggests continued HCC surveillance in patients with HBsAg loss after ages >40 years for males and >50 years for females [6,9].
TREATMENT GOALS AND AIMS
The treatment goals and aims were updated in the KASL guidelines [9]. The goals of treatment are to decrease mortality due to liver disease and improve survival by preventing the progression of liver fibrosis to cirrhosis and preventing HCC, which are consistent with other guidelines [7,8]. The aims of anti-HBV treatment suggested by the KASL include ALT normalization, undetectable serum HBV DNA, serum HBeAg loss or seroconversion, and serum HBsAg loss or seroconversion [9]. Specifically, serum HBsAg loss or seroconversion is proposed as an ideal endpoint for CHB treatment [9]. The EASL also suggests HBsAg loss with or without anti-HBs seroconversion as an optimal endpoint, whereas the APASL considers HBsAg loss an ideal, although not realistic, endpoint [7,8]. Hence, the APASL suggests a sustained off-therapy virological response in both HBeAg-positive (with HBeAg to anti-HBe seroconversion) and HBeAg-negative patients as a satisfactory endpoint [8].
WHEN TO START: COMPARISON OF TREATMENT INDICATORS
High level HBV replication is associated with an increased risk of liver damage and liver-related complications [23,24]. Antiviral therapy using interferons or nucleos(t)ide analogs (NAs) efficiently reduces these risks by suppressing HBV replication [25-29]. Current guidelines recommend treatment initiation with antiviral agents before the accumulation of liver injury or progression of fibrosis. However, intrahepatic covalently closed circular DNA cannot be eradicated, even with long-term treatment [6-9]. To determine when to initiate antiviral treatment, the level of HBV replication by HBV DNA measurement, the degree of liver injury measured by ALT or liver biopsy, and the stage of liver fibrosis assessed by noninvasive methods or liver biopsy should be considered (Fig. 1) [9,30]. Additionally, information regarding age, co-morbidity, and family history of HCC or liver cirrhosis may be helpful in determining when to start treatment.
CHB, immune tolerant phase
Previously, most practice guidelines did not recommend antiviral therapy for CHB patients in the immune tolerant phase (Table 3) [17,31]. Recent data regarding the treatment of CHB patients in the immune tolerant phase suggest that the risk of progression to liver cirrhosis and HCC development could be reduced by antiviral therapy [13,32]. Therefore, patients needing treatment should be differentiated from truly immune tolerant CHB patients who do not require antiviral therapy. However, initiation of antiviral therapy for patients in the immune tolerant phase remains very controversial [6-8]; further studies are needed to appropriately define the immune tolerant phase, as discussed above.
The KASL guidelines suggest liver biopsy if the patient is ≥30–40 years of age, the serum HBV DNA levels are <107 IU/mL, a noninvasive fibrosis test shows a range of significant hepatic fibrosis, or ALT is at the borderline of the ULN [9]. Biopsy findings of moderate to severe inflammation (≥A2) or significant fibrosis (≥F2) are treatment indicators. Age cut-offs for the consideration of liver biopsy or treatment vary among the guidelines and are >40 years according to the AASLD, >30 years according to the EASL, and >35 years according to the APASL [6-8]. The EASL specifically emphasizes the age; it recommends starting treatment regardless of the severity of histological liver lesions if a patient is >30 years of age [7]. However, this recommendation requires further validation. In other cases, histological criteria should be used to determine when to initiate treatment; these values are the same among the guidelines (≥A2 or ≥F2) [6-9].
CHB, immune active phase
Antiviral treatment during the immune active phase decreases the risk of liver cirrhosis, hepatic decompensation, and HCC [25-29]. Therefore, antiviral therapy is recommended for patients in this phase. The criteria for treatment differ slightly among the guidelines (Table 3). Regarding HBV DNA levels, the KASL, AASLD, and APASL suggest levels of ≥20,000 IU/mL for HBeAg-positive and ≥2,000 IU/mL for HBeAg-negative CHB as treatment indicators if ALT is elevated >2× ULN [6-9]. If the ALT levels are 1–2× ULN, liver biopsy or noninvasive fibrosis tests are necessary to determine whether treatment should be initiated [6-9]. The EASL recommends the treatment of patients with HBV DNA >20,000 IU/mL and ALT >2× ULN, regardless of the degree of fibrosis, whereas all patients with HBV DNA >2,000 IU/mL and ALT >1× ULN require fibrosis assessment before treatment (≥A2 or F2) [7]. Previously, a 3–6 months monitoring period was recommended for HBeAg-positive immune active CHB patients expecting spontaneous HBeAg seroconversion [8,17]. However, this is currently not recommended by the KASL and international guidelines, with the exception of the APASL, owing to an increased risk of liver failure during the follow-up period [6-9,33]. Additionally, most guidelines recommend immediate antiviral therapy for patients with acute exacerbation, such as elevation of ALT to ≥5–10× ULN or signs of liver failure [6-9,34].
On the contrary, for HBeAg-negative patients with elevated HBV DNA levels (≥2,000 IU/mL) and normal ALT levels, treatment may be delayed or considered after liver biopsy, because these patients are considered to be in a gray area or transitional zone [6-9]. The KASL, EASL, and APASL also recommend noninvasive fibrosis tests to assess these patients [6,7,9].
CHB, immune inactive phase
The KASL suggested that the immune inactive phase, which features low HBV DNA levels (<2,000 IU/mL) and normal ALT, is not an indicator for antiviral therapy [9]. However, the EASL and APASL recommend considering treatment if there is a family history of HCC or liver cirrhosis or significant histological findings upon liver biopsy [7,8]. Considering that HBsAg loss is an ideal endpoint for therapy, treatment of CHB in this phase may facilitate HBsAg clearance [35]; thus, the treatment strategy could be changed in the future.
Compensated liver cirrhosis
Most guidelines recommend treating compensated liver cirrhosis if the HBV DNA level is ≥2,000 IU/mL, regardless of the ALT level [6-9]. Furthermore, even patients with detectable but low HBV DNA (<2,000 IU/mL) should be considered for treatment (Table 4) [6-9]. This approach is supported by recent data regarding the decrease in liver-related events induced by NA therapy in cirrhotic patients with low level viremia [36].
Decompensated liver cirrhosis
Antiviral therapy should be initiated regardless of the ALT level if serum HBV DNA is detected in patients with decompensated liver cirrhosis [6-9]. Preferably, all HBsAg-positive decompensated cirrhosis patients should receive antiviral therapy, even if HBV DNA is not detected. However, the benefits of NAs for HBV DNA-undetected patients require further studies. Liver transplantation should also be considered (Table 4) [8].
WHAT TO CHOOSE: SELECTION OF ANTIVIRAL AGENTS
Pegylated interferon
Interferons and oral NAs represent the currently available antiviral agents [5-9,37]. Among interferons, pegylated interferon (peg-interferon) replaced conventional interferon owing to its onceweekly dosing and improved efficacy [37,38]. However, various adverse events and the inconvenience associated with the injection of peg-interferon have limited its use despite its unique immune-modulatory actions [37-39]. Nonetheless, peg-interferon should be considered for a finite duration of treatment achievable by the immune-mediated control of HBV, leading to sustained off-treatment responses [37-39]. Peg-interferon is not preferred in patients with liver cirrhosis due to safety concerns and is contraindicated for decompensated cirrhosis patients by all international guidelines [6-9].
NAs
Contrary to interferons, NAs are directly acting antiviral agents that inhibit HBV replication and have no fixed treatment duration [6-9]. NAs are now widely used for CHB treatment owing to their low incidence of adverse effects as well as convenience. Antiviral resistance was a major drawback of first-generation NAs (lamivudine and adefovir). Resistance was very rare in second-generation NAs (entecavir and tenofovir disoproxil fumarate [tenofovir DF]) [40-42]. Additionally, newer generation drugs (besifovir dipivoxil maleate [besifovir] and tenofovir alafenamide fumarate [tenofovir AF]) have alleviated the safety concerns associated with tenofovir DF (renal and bone toxicity), while maintaining a high genetic barrier to resistance [43-45]. Therefore, the KASL recommends NAs with a high genetic barrier to resistance, including entecavir, tenofovir DF, tenofovir AF, and besifovir, rather than those with a low genetic barrier to resistance (lamivudine, telbivudine, clevudine, and adefovir) as first-line agents for CHB treatment [9].
Lamivudine and adefovir have been used for extended periods but are no longer recommended given their low potency and high incidence of resistance [42,46]. Telbivudine and clevudine are comparable to entecavir in their antiviral potency but are currently not recommended owing to the frequent development of antiviral resistance and serious muscle-related problems [42,46-49].
Entecavir and tenofovir DF have been the preferred antiviral agents for more than a decade since their approval for CHB treatment. Recently, these drugs were compared in terms of long-term treatment outcomes, especially for the prevention of HCC [50-53]. The initial report using data from the Korean National Health Insurance Service database suggested that tenofovir DF was associated with a significantly lower risk of HCC compared to entecavir [50]. However, subsequent reports using multicenter academic teaching hospital data were contradictory and found no difference between the two therapies regarding the incidence of HCC, all-cause mortality, and liver transplantation, even after a thorough adjustment of baseline characteristics [51,52]. The issue remains contentious and requires further longer term and larger scale studies with the appropriate adjustment of possible biases to reach a consensus [53].
Currently, generic and less expensive forms of entecavir and tenofovir (tenofovir disoproxil or tenofovir fumarate aspartate) are available in Korea and other countries, which can improve the cost-effectiveness of antiviral treatment [54,55]. Unfortunately, there is limited clinical data on the antiviral efficacy of generic antiviral drugs for CHB [55].
Tenofovir AF is a nucleotide reverse transcriptase inhibitor and a novel prodrug of tenofovir. It has greater plasma stability than tenofovir DF and efficiently delivers the active form of tenofovir to hepatocytes at a lower dose [44,45]. In phase 3 clinical trials, tenofovir AF was found to be as effective as tenofovir DF and induced significantly smaller decreases in the estimated glomerular filtration rate and spine/hip bone density than tenofovir DF after up to 96 weeks of treatment [44,45].
Besifovir is an acyclic nucleotide phosphonate developed in Korea that was approved by the Ministry of Food and Drug Safety in 2017 [43]. However, it is still not available outside Korea. The KASL guidelines are the first to include besifovir as one of the initial choices for CHB treatment [9]. The advantage of besifovir over tenofovir DF has been well described [43]. Briefly, in phase 3 randomized controlled trials, besifovir was comparable to tenofovir DF in terms of antiviral efficacy after 48 weeks of treatment. Additionally, the renal and bone safety profiles of besifovir were superior to those of tenofovir DF. The estimated glomerular filtration rate and hip/spine bone mineral density were significantly higher in the besifovir group than in the tenofovir DF group [43]. After 48 weeks, all patients were rolled over into an open-label extensional study where everyone received besifovir. In patients who switched from tenofovir DF to besifovir, the estimated glomerular filtration rate and hip/spine bone mineral density improved to baseline levels at 96 weeks [43].
Currently, there is limited data regarding the use of besifovir or tenofovir AF in patients with decompensated liver cirrhosis or HCC. However, there seems to be no reason not to use these drugs. In the future, more data regarding besifovir and tenofovir AF will be available for CHB patients in various situations. The AASLD and EASL recommend entecavir, tenofovir DF, and tenofovir AF monotherapy as the preferred regimens for the treatment of CHB and liver cirrhosis patients. The APASL only recommends entecavir and tenofovir DF, likely owing to the limited data available at the time of its publication in 2016 [6-8].
No guidelines recommend a combination of peg-interferon and NA or a combination of NAs as initial therapy due to their limited benefits [6-9].
WHEN TO CHANGE: TREATMENT MODIFICATIONS
Partial virological responses (PVR)
Although the antiviral efficacy of drugs has remarkably improved, patients with very high HBV DNA levels may show PVR featuring a decreased but still detectable level of HBV DNA after at least 48 weeks of continued treatment with high genetic barrier drugs. Other causes of PVR include decreased susceptibility owing to previous drug exposure, decreased medication compliance, and altered drug metabolism. The clinical significance of low level viremia due to PVR is unclear although an increased risk of liver-related complications was found in patients with advanced liver diseases [36,56].
There are slightly different definitions of PVR. They are summarized in Table 5. Briefly, the KASL defines PVR at different time points based on the genetic barrier of the drugs, at 48 weeks of therapy for high genetic barrier drugs and at 24 weeks for low genetic barrier drugs [9]. The APASL defines PVR as detectable HBV DNA at 24 weeks of therapy, whereas the EASL and AASLD define PVR or persistent viremia at 48 weeks and 96 weeks of entecavir or tenofovir treatment, respectively [6-8].
Modification of therapy may be considered for PVR, especially when using low genetic barrier drugs (Table 5). However, the recommendations for managing PVR during entecavir or tenofovir DF therapy are not consistent across the guidelines (Table 5). All guidelines indicate that high genetic barrier drugs can be continued, with the possibility of switching to another high genetic barrier drug (KASL, EASL) or add-on (EASL), especially in patients with advanced liver diseases [6-9]. The AASLD argues that there is insufficient comparative evidence to advocate the addition of a second drug or switching to another drug. However, a recent randomized controlled trial compared switching to tenofovir DF with continuation of entecavir for the treatment of CHB with PVR and observed a better virological outcome upon switching to tenofovir DF [57]. Hence, the KASL recommends switching to tenofovir DF for patients with entecavir PVR [9].
Antiviral resistance
Although antiviral resistance is uncommon in previously treatment-naïve patients receiving high genetic barrier drugs, entecavir resistance was found in 1–3% of patients, and variants resistant to tenofovir DF have been identified [40,42,58,59]. Entecavir resistance rates increase up to 50% in the fifth year in treatment-experienced or refractory patients [40,42]. Adefovir monotherapy also has a high risk of resistance in patients with lamivudine resistance with up to 25% resistance at two years of treatment, leading to multidrug resistance [60,61]. The collective findings highlight the importance of paying attention to patients’ adherence to medication; antiviral resistance testing should be performed in case of virological breakthrough [42].
After antiviral resistance is confirmed, it is assumed that one of two strategies can be applied: switching to another class of antiviral monotherapy with a high genetic barrier to resistance or adding a second antiviral drug that lacks cross-resistance (Table 6). The recent KASL guidelines recommend that patients with resistance to L-nucleoside analogs (lamivudine and telbivudine) be switched to tenofovir DF/AF [9]. For adefovir or entecavir resistance, switching to tenofovir DF/AF monotherapy or a combination of tenofovir DF/AF and entecavir is recommended. For multidrug resistance, switching to a combination of tenofovir DF/AF and entecavir or tenofovir DF/AF monotherapy is recommended [9]. Similar recommendations were provided by the AASLD, EASL, and APASL favoring tenofovir DF/AF monotherapy, except in cases of multidrug resistance [6-8]. However, considering recent reports of the long-term efficacy of tenofovir DF for multidrug resistance, tenofovir DF/AF monotherapy could also be a safe option [62,63].
There are insufficient data regarding tenofovir resistance, although guidelines recommend adding or switching to entecavir. In these cases, it is likely that new antiviral agents other than NAs, such as capsid assembly inhibitors, may be needed [58].
Adverse effects
NAs are relatively safe drugs, even with long-term use. However, all drugs may have side effects. Clinically significant adverse effects associated with NA therapy include lactic acidosis (entecavir, tenofovir DF, adefovir, lamivudine, and telbivudine), nephropathy, osteomalacia, Fanconi syndrome (tenofovir DF and adefovir), increasing low-density lipoprotein cholesterol (tenofovir AF), carnitine depletion (besifovir), pancreatitis (lamivudine), peripheral neuropathy, creatinine kinase elevation, and myopathy (telbivudine and clevudine) [9]. When NA-related adverse effects are suspected, it is essential to confirm the diagnosis. In cases of serious complications, immediate cessation of the drug or switching to another drug should be considered. For example, switching to entecavir or tenofovir DF is a reasonable option for clevudine- or telbivudine-associated myopathy [48,49,64].
Among the high genetic barrier drugs preferred as first-line agents for CHB treatment, tenofovir DF has an increased risk of renal and bone toxicity [65]. The KASL recommends substituting tenofovir DF with entecavir, tenofovir AF, or besifovir in such patients based on previous treatment history [9]. The AASLD and EASL also recommend that patients using tenofovir DF who are at risk of developing and/or have underlying renal dysfunction or metabolic bone disease consider switching to entecavir or tenofovir AF, depending on their previous lamivudine exposure [6,7]. For lamivudine or other NA-experienced or refractory patients, tenofovir AF is preferred to entecavir.
WHEN TO STOP: TREATMENT CESSATION
The standard duration of peg-interferon therapy is 48 weeks for HBeAg-positive or -negative CHB [38,66]. Thus, it would be acceptable to stop treatment after the planned schedule is completed. Extending the treatment duration may be more effective for HBeAg-negative CHB [67,68] but cannot be routinely recommended (Table 7).
There is no predefined duration for NA therapy. As such, stopping NAs before achieving the ultimate goal of antiviral therapy, which is the improvement of survival by the prevention of liver disease progression and HCC development [7-9], may lead to the loss of treatment benefits and risk clinical exacerbations. Therefore, appropriate biomarkers are needed for proper decision making regarding cessation of NA therapy.
HBeAg-positive CHB
Previously, HBeAg loss or seroconversion was considered an indication to stop therapy in HBeAg-positive CHB [17,69]. Cessation of antiviral therapy was recommended after 12 months of consolidation therapy. However, most patients experienced virological or clinical relapse. On the contrary, HBsAg loss or seroconversion is rare during antiviral therapy, but the prognosis of patients who cleared HBsAg is much improved; relapse of viral replication is very rare, and liver transplant-free survival or HCC-free survival is significantly better than for those who did not clear HBsAg [22]. Based on this information, the KASL and EASL guidelines suggest that HBsAg loss is the ideal endpoint of therapy and should be the primary goal [7,9]. Still, the AASLD and APASL consider HBeAg seroconversion as a satisfactory endpoint, probably owing to the rarity of HBsAg loss (Table 7) [6,8].
HBeAg-negative CHB
Relapse is common after stopping antiviral therapy in HBeAg-negative CHB patients owing to the presence of immune escape mutants [70]. Therefore, the AASLD suggests that treatment may be continued indefinitely or until HBsAg is lost [6]. The KASL and EASL also suggest the cessation of NAs after HBsAg loss (Table 7) [7,9]. However, the EASL also proposed that NA discontinuation may be considered in select patients with long-term (≥3 years) virological suppression under NAs [7]. Similarly, the APASL suggested that treatment be withdrawn after HBsAg loss following either anti-HB seroconversion or at least 12 months of consolidation therapy. Otherwise, at least ≥2 years of consolidation therapy confirming undetectable HBV DNA levels on three separate occasions can justify the end of treatment (Table 7) [8]. However, undetectable HBV DNA levels cannot likely be the sole factor in determining treatment cessation because most patients experience virological relapse after stopping therapy in the presence of HBsAg [70,71]. Recently, a low HBsAg titer (<2 log IU/mL) was proposed as an indicator of safe cessation of therapy before HBsAg loss, although further clinical experience may be necessary [72,73].
CONSIDERATIONS FOR SPECIAL POPULATIONS
CHB patients may face situations requiring special consideration. HCC may develop, accompanying renal or bone abnormalities may be detected, and anticancer chemotherapy or immunosuppressive therapy may be needed. Table 8 summarizes representative special conditions and compares international guidelines.
Renal dysfunction or metabolic bone disease
Patients who develop renal dysfunction or decreased bone density during tenofovir DF or adefovir treatment may need to change medication, as described above concerning adverse effects [65]. If a treatment-naïve patient has pre-existing renal dysfunction (estimated glomerular filtration <60 min/mL/1.73 m2, dipstick proteinuria, urine albuminuria/creatinine >30 mg/g, or serum phosphate <2.5 mg/dL) or metabolic bone disease (chronic steroid use, taking medication that worsens bone density, or pre-existing osteoporosis/osteopenia) before starting the therapy, entecavir, tenofovir AF, and besifovir are preferred for treatment by the KASL. Although the AASLD previously suggested that there was no preference between entecavir or tenofovir DF regarding the potential long-term risk of renal and bone complications [74], their updated guidance recommends switching to tenofovir AF or entecavir if tenofovir DF-associated renal dysfunction or bone disease is suspected [6]. The EASL made detailed recommendations regarding renal or bone abnormalities in terms of when to consider entecavir or tenofovir AF over tenofovir DF when initiating antiviral therapy [7]. Similar criteria have been proposed by the KASL, as described above (Table 8). The EASL also included age >60 years, history of fragility fracture, and hemodialysis for similar candidates, but individualized approaches are needed [7]. These criteria must be clinically validated further [7]. The NA doses in all patients with renal dysfunction should be adjusted according to their creatinine clearance [9].
HCC
Only the KASL and APASL have recommendations for patients with HBV-related HCC (Table 8) [8,9]. Given that HCC is one of the most serious complications in CHB patients, appropriate measures should be taken. Importantly, antiviral therapy reduces both the incidence of de novo HCC and the recurrence of HCC in this population [25-29,75-77]. Furthermore, the reactivation of HBV can be effectively prevented by prophylactic antiviral therapy during anticancer treatment [78,79]. Therefore, the KASL recommends starting NAs before and during HCC treatment if HBV DNA is detected or prophylactically, even if HBV DNA is not detected [9]. All HBsAg-positive patients should receive NAs after HCC diagnosis, regardless of HBV DNA detection, but this requires confirmation in future studies.
Immunosuppression or chemotherapy
Patients with chronic HBV infection are at an increased risk of hematological and solid malignancies [80,81]. Therefore, the chance of receiving immunosuppression or anticancer chemotherapy is relatively high in CHB patients. If the immune system is suppressed by immunosuppression or chemotherapy, HBV can reactivate and lead to severe hepatic injury via the acute exacerbation of chronic HBV infection in HBsAg-positive patients or relapse of past HBV infection in HBsAg-negative/anti-HBc-positive patients [82-84]. HBV reactivation during anticancer chemotherapy has occurred in 41–53% of HBsAg-positive anti-HBc-positive patients and in 8–18% of HBsAg-negative anti-HBc-positive patients [6,85,86]. If reactivation occurs, dose reduction or discontinuation of anticancer therapy is necessary, which adversely affects the outcomes of cancer treatment. As such, HBsAg and anti-HBc testing should be performed in all patients before initiating any immunosuppressive or cytotoxic chemotherapy [6-9]. Additionally, particular caution should be exercised with high risk (>10% of reactivation) treatments using B cell-depleting agents (rituximab, ofatumumab, natalizumab, alemtuzumab, and ibritumomab), high-dose corticosteroids (prednisone ≥20 mg/day, ≥4 weeks), anthracyclines (doxorubicin and epirubicin), potent tumor necrosis factor-alpha inhibitors (infliximab, adalimumab, certolizumab, and golimumab), and local therapy for HCC (transcatheter arterial chemoembolization) [9,87]. High (>10%), moderate (1–10%), and low (<1%) risk of HBV reactivation in response to immunosuppressive or anticancer chemotherapy is well described in the KASL guidelines [9]. Currently, most guidelines, including the KASL, AASLD, ESAL, and APASL, recommend the initiation of NAs (entecavir or tenofovir DF/AF) before immunosuppression or chemotherapy in HBsAg-positive or HBV DNA-detected patients (Table 8) [6-9]. Not all patients who are exclusively anti-HBc-positive (HBsAg-negative and HBV DNA-undetectable) require routine administration of NAs before immunosuppression or chemotherapy. However, NA therapy should be initiated promptly if there is a high risk of reactivation (e.g., treated with a rituximab-containing regimen) or detectable HBV DNA and/or reversion of HBsAg during follow-ups. NAs should be continued during and at least 6 months (or 12 months for rituximab therapy) after the cessation of immunosuppressive therapy or chemotherapy [6-9].
Pregnant women
Immunological changes occur during pregnancy, and HBV may replicate more actively [88]. Immune responses are restored at the late phase of pregnancy or after delivery, leading to ALT flares. Hence, NA therapy may need to be initiated in patients during or after pregnancy [89,90]. Moreover, a high level of HBV DNA is related to an increased risk of mother-to-child viral transmission despite vaccine administration and hepatitis B immune globulin prophylaxis [88]. Currently, the NAs evaluated for safety and efficacy during pregnancy include lamivudine [91], telbivudine [92], and tenofovir DF [93-95]. Among these, tenofovir DF is the preferred NA owing to its excellent potency and high genetic barrier to resistance. Most guidelines recommend using tenofovir DF over other NAs for CHB treatment during pregnancy (Table 8). Additionally, the prophylactic use of tenofovir DF is recommended to prevent mother-to-child transmission beginning at 24–32 weeks of pregnancy (24–28 weeks by the EASL, 28–32 weeks by the AASLD and APASL, and 24–32 weeks by the KASL) and continuing until 2–12 weeks after delivery if pregnant women show serum HBV DNA levels >200,000 IU/mL [6-9].
The KASL, AASLD, and EASL agree that breastfeeding is generally not contraindicated, even if tenofovir DF is being administered to the mother, based on previous studies [6,7,9,96]. However, the AASLD is somewhat cautious about this issue, suggesting there are insufficient long-term safety data [6]. The APASL discourages breastfeeding during maternal NA treatment, which may need to be updated [8].
Acute hepatitis B
Although acute hepatitis B is generally a self-limiting disease, severe cases resulting in hepatic failure, liver transplantation, or even death have been reported, albeit uncommonly [97]. The use of antivirals in severely ill patients has been debated. While NA therapy might delay HBsAg sero-clearance, NA therapy can significantly reduce the mortality rate in patients with severe acute hepatitis B [98]. Considering this, the KASL guidelines recommend initiating NA therapy in patients with severe acute hepatitis B (e.g., coagulopathy, severe jaundice, or liver failure) in agreement with other guidelines [9].
The AASLD recommends using entecavir or tenofovir DF/AF, whereas the EASL refrains from recommending tenofovir AF owing to a lack of data [6,7]. The APASL includes lamivudine, telbivudine, or adefovir for severe acute hepatitis B considering their relatively short therapy duration [8]. They also recommend initiating NA treatment when it is difficult to distinguish between true severe acute hepatitis B and spontaneous reactivation of chronic HBV infection [8].
CONCLUSIONS
The KASL clinical practice guidelines for the management of CHB were recently revised, given the emergence of new NAs and continuously updated data regarding treatment initiation, modification, and cessation. Considering the 4- to 5-year interval of guideline revisions, other international guidelines are expected to be updated soon. Through a thorough and systematic approach for the management of CHB based on clinical practice guidelines, the cure of chronic HBV infection is expected to be a real treatment endpoint in the near future.
Notes
Authors’ contribution
YHJ conceptualized and designed the study. YHJ, KJH, PJY, YEL, PH, KJH, SDH, LSH, LJ-H, and LHW performed a review of literature, revised the current KASL guidelines, and incorporated those revisions into the manuscript through interactive discussion. YHJ wrote the manuscript. YHJ, KJH, PJY, YEL, PH, KJH, SDH, LSH, LJH, and LHW reviewed and approved the final submission of the manuscript.
Conflicts of Interest: YHJ received research funds from Gilead Sciences Korea, Ildong Pharm, and Yuhan Corporation. LJ-H received honoraria from Gilead Science Korea, and Daewoong Pharm during the conduct of the study. KJH, PJY, YEL, PH, KJH, SDH, LSH, and LHW have nothing to disclose.
Acknowledgements
This work was funded in part by the Korean Association for the Study of the Liver and Korea University Research Grants.