Risk of Hepatitis B Virus Reactivation in Rheumatoid Arthritis Patients Undergoing Tocilizumab-Containing Treatment.

BACKGROUND AND AIM: To investigate the risk of hepatitis B virus reactivation in patients undergoing long-term tocilizumab therapy for rheumatoid arthritis.
METHOD: From January 2011 through August 2019, a total of 97 patients were enrolled in this retrospective study. Clinical data, comedications, and the occurrence of HBV reactivation were recorded.
RESULTS: Seven patients were HBsAg+ (7.2%), 64 were HBsAg-/HBcAb+ (65.9%), and 26 were HBsAg-/HBcAb- (26.8%). The median disease follow-up time was 9 years. TCZ was administered for a median of 29 months. Four patients (4.1%) experienced HBV reactivation after tocilizumab therapy. Of the 7 HBsAg+ patients, 4 received antiviral prophylaxis and had no HBV reactivation; the remaining 3 patients did not receive antiviral prophylaxis, and all 3 (100%) experienced HBV reactivation and hepatitis flare-up. Hyperbilirubinemia occurred in 2 of these 3 patients, with mild prothrombin time prolongation in one. After salvage entecavir treatment, all patients had a favorable outcome. Of the 64 HBsAg-/HBcAb+ patients, only one became positive for serum HBV DNA (2.5 × 107 IU/mL) after 18 months of tocilizumab treatment (1.6%; 1/64). This patient was immediately treated with entecavir, which prevented hepatitis flare-up.
CONCLUSIONS: Tocilizumab is widely used in treating rheumatoid arthritis and has the potential to reduce the mortality rate among severe COVID-19 patients. However, HBV reactivation needs to be considered. HBsAg+ patients have a high risk of HBV reactivation, which could be prevented by antiviral prophylaxis. Although the risk of reactivation is low in HBsAg-/HBcAb+ patients, strict monitoring is necessary.

Introduction

The risk of hepatitis B virus (HBV) reactivation during immunosuppressive therapy in patients with chronic or occult HBV infection is increasingly recognized in different disciplines of medicine, including rheumatology [1, 2]. The consequences of HBV reactivation during immunosuppressive therapy range from an asymptomatic increase in serum HBV DNA levels to fatal hepatic failure [3]. In rheumatoid arthritis (RA), HBV can be reactivated by changes in the disease course and by drug use [4-7]. Inflammatory arthritis patients receiving biological disease-modifying antirheumatic drugs (bDMARDs) are thought to have a moderate risk (1–10%) of HBV reactivation [7]. A previous study reported that without antiviral prophylaxis, HBV reactivation occurs in 62.5% of HBV carriers and 25% of patients with occult HBV infection undergoing treatment with tumor necrosis factor (TNF)-alpha blockers [8].

Tocilizumab (TCZ), a humanized monoclonal antibody that selectively neutralizes both the soluble and membrane-bound forms of interleukin (IL)-6 receptor, is a developed biological agent that effectively alleviates RA disease symptoms. Recently, tocilizumab has been applied in patients with severe COVID-19 to reduce the cytokine storm and has the potential to reduce the mortality rate [9, 10]. However, the risk of HBV reactivation needs to be considered. Several studies have revealed that IL-6 could suppress HBV replication and mediate HBV entry into hepatocytes [11, 12]. Nonparenchymal liver cells, most likely Kupffer cells, recognize HBV patterns and induce the IL-6-mediated block of HBV replication at the transcriptional level [13]. IL-6 inhibits HBV replication through a moderate reduction in viral transcripts, similar to IL-4 and transforming growth factor -β1, and a more dramatic reduction in viral genome-containing nucleocapsids, similar to interferon [14]. In addition, the accumulation of HBV covalently closed circular DNA could be blocked by IL-6 [14]. Therefore, biological agents that therapeutically decrease IL-6 levels, such as tocilizumab, may present a risk of HBV reactivation.

Current treatment guidelines suggest that antiviral prophylaxis should be initiated before immunosuppressive or cytotoxic therapy in HBV surface antigen-positive (HBsAg+) patients [7, 15, 16]. However, determining the risk of TCZ-induced HBV reactivation is difficult due to a lack of prospective controlled studies. Studies investigating the risk of HBV reactivation in HBsAg+ patients receiving TCZ have demonstrated controversial results [17-20]. The reactivation rate ranged from 0 to 60% in HBsAg+ patients who underwent TCZ without antiviral prophylaxis [17-19], and in one case, the patient even required liver transplantation due to hepatic failure [21]. For HBsAg−/HBV core antibody-positive (HBcAb+) patients, the HBV reactivation rate is also inconsistent [19, 22–27], and HBV reactivation always presents with virus reappearance and fluctuation [28-31]. These controversial results have increased the interest in studying the HBVr risk of TCZ.

The aim of this retrospective, real-world study was to determine the risk of HBV reactivation with long-term TCZ therapy for RA patients in our hospital.

Methods

Patients

We retrospectively reviewed the medical records of RA patients who had received TCZ therapy between January 2011 and August 2019 at Dalin Tzu Chi Hospital. The inclusion criteria were as follows: (1) fulfilled the RA classification criteria [32, 33]; (2) available HBsAg and HBcAb status at diagnosis; and (3) treated with TCZ for at least 3 months. Patients were excluded if they were < 20 years of age or lacked the required data. In accordance with international guidelines, TCZ was administered at the standard intravenous dose of 4–8 mg/kg every 4 weeks or subcutaneous dosage of 162 mg every 1–2 weeks [34].

Follow-Up of the Study Population

Medical records were reviewed retrospectively. Baseline characteristics included serum markers of HBV [HBsAg, HBcAb, hepatitis B surface antibody (HBsAb), and HBV DNA], anti-hepatitis C virus antibody (anti-HCV), liver biochemical parameters [serum aspartate aminotransferase (AST); alanine aminotransferase (ALT)], comorbidities, comedications, and the occurrence of HBV reactivation. Patients were monitored for ALT/AST levels every 3 months, and HBsAg and HBV DNA tests were performed whenever clinically indicated. Detailed medical records were collected, including immunological profiles, TCZ course, previous and concomitant DMARD therapy, and corticosteroid therapy.

Assessment of HBV Reactivation and Hepatitis Flare-Up

The primary endpoint of this study was HBV reactivation. For HBsAg+ patients, HBV reactivation was defined as (1) an increase in HBV DNA > 2 log10 over that of baseline,(2) HBV DNA > 3 log10 in a patient with previously undetectable level, or (3) an absolute level of HBV DNA > 4 log10 if baseline level was unavailable [15]. A change in the HBV DNA titer from negative to positive or HBsAg seroreversion (HBsAg reappearance) was defined in HBsAg−/HBcAb+ [15]. Hepatitis flare-up was defined as an ALT level elevated at least 3 times that of baseline and > 100 U/L [15].

Statistical Analysis

The data were analyzed using SPSS 19.0 for Windows (SPSS, Inc., Chicago, IL, USA). Categorical variables are presented as counts and percentages, and continuous variables are presented as the median value and range.

Results

General Characteristics of the Study Subjects

The enrolled patient distribution is illustrated in Fig. 1. Of the initial 134 RA patients receiving TCZ, 97 remained after the exclusion of patients with missing data regarding the HBsAg or HBcAb status (n = 25) or those who received TCZ for less than 3 months (n = 12). Of the included 97 patients, 7 were HBsAg+ (7/97, 7.2%), and 90 were HBsAg− (90/97, 92.8%). Of the HBsAg− patients, 64 were HBsAg−/HBcAb+ , and 26 were HBsAg−/HBcAb−. Four patients (4/97) experienced HBV reactivation during TCZ treatment. The HBV reactivation rate was 5.6% (4/71) in the patients with a chronic or resolved HBV infection.

Fig. 1

Flow diagram of study cohort characteristics. The flowchart shows the hepatitis B virus (HBV) infection serostatus distribution at baseline and the occurrence of HBV reactivation in rheumatoid arthritis (RA) patients treated with tocilizumab. Abbreviations: HBsAg, HBV surface antigen; HBcAb, HBV core antibody

The clinical, serological, and virologic characteristics and therapeutic regimens of the patient cohort are shown in Table 1. The median age was 64 years (range, 38–87), and 75 (77%) were female. The median disease follow-up time was 9 years (range, 1–18 years). TCZ was administered for a median of 29 months (range, 3–91) in combination with methotrexate (71 patients, 73%) or a low dose of glucocorticoids (90 patients, 94%). Seventy-one (73%) patients had a history of other bDMARD treatments. Most patients had previously received adalimumab (45 patients; 46%) or rituximab (25 patients; 26%).

Table 1

Baseline patient characteristics

	All(N = 97)	HBsAg+(N = 7)	HBsAg−/HBcAb+(N = 64)
Age (years)a	64 (38–87)	65 (56–78)	67 (38–87)
Sex, female n (%)	75 (77%)	5 (71%)	49 (77%)
Follow-up time (years)a	9 (1–18)	9 (2–14)	9 (1–18)
Duration of TCZ therapy (months)a	29 (3–91)	16 (4–66)	26 (3–84)
Anti-HCV (+), n (%)	14 (14%)	1 (14%)	11 (17%)
RF (IU/ml)	505 (10–6710)	131 (10.4–430)	529 (10–6710)
Anti-CCP (EliA U/ml)	74 (0.3–448)	98 (0.3–340)	72 (0.3–448)
IgG (mg/dL)	1578 (664–2640)	1754 (1210–2240)	1561 (664–2640)
Antirheumatic therapies before TCZ use, n (%)
sDMARDs
Methotrexate	91 (94%)	7 (100%)	62 (97%)
Azathioprine	3 (3%)	0 (0%)	3 (5%)
Cyclosporine	15 (15%)	3 (43%)	9 (14%)
Leflunomide	45 (46%)	3 (43%)	26 (41%)
Sulfasalazine	85 (88%)	6 (86%)	57 (89%)
Glucocorticoid (oral)b	96 (99%)	7 (100%)	63 (98%)
bDMARDs
Abatacept	10 (10%)	1 (14%)	8 (17%)
Adalimumab	45 (46%)	3 (43%)	31 (48%)
Etanercept	22 (23%)	2 (29%)	11 (17%)
Golimumab	13 (13%)	1 (14%)	8 (13%)
Rituximab	25 (26%)	3 (43%)	12 (19%)
bDMARD naïve	26 (27%)	0 (0%)	19 (30%)
Concomitant, n (%)
Methotrexate	71 (73%)	4 (57%)	47 (73%)
Glucocorticoid (oral)b	96 (99%)	7 (100%)	64 (100%)
Equivalent dose (mg)c	5 (2–10)	5 (2.5–7.5)	5 (2–10)
Low dose	90 (94%)	7 (100%)	58 (91%)
Moderate dose	6 (6%)	0 (0%)	6 (9%)
Azathioprine	1 (1%)	0 (0%)	1 (2%)
Cyclosporine	4 (4%)	1 (14%)	3 (5%)
Leflunomide	21 (22%)	0 (0%)	13 (20%)
Sulfasalazine	45 (47%)	3 (43%)	28 (42%)

aData are presented as the median (range)

bGlucocorticoids (oral): cortisone, prednisolone, methylprednisolone, dexamethasone

cPrednisolone equivalent dose (mg/day): high dose, > 20 mg/day ≥ 4 weeks; moderate dose, 10–20 mg/day ≥ 4 weeks; low dose, < 10 mg/day ≥ 4 weeks

HCV, hepatitis C virus; RF, rheumatoid factor; Anti-CCP, anti-cyclic citrullinated peptide antibody; IgG, Immunoglobulin G,HBsAg, HBV surface antigen; HBcAb, HBV core antibody; TCZ, tocilizumab; bDMARDs, biological disease-modifying antirheumatic drugs; sDMARDs, synthetic disease-modifying antirheumatic drugs

Clinical Features of HBsAg+ Patients with HBV Reactivation

The general characteristics of the HBsAg+ patients are shown in Table 1. Four patients (57.1%) received antiviral prophylaxis, and none experienced HBV reactivation or hepatitis flare-up among the 4 HBsAg+ patients. In contrast, HBV reactivation and hepatitis flare-up were noted in all 3 patients without antiviral prophylaxis (Fig. 1). Clinical data for the patients with HBV reactivation are shown in Table 2. All were female (median age, 77 years; range, 56–78 years), and the median time to reactivation from the initiation of TCZ treatment was 6 months (range, 5–8 months). Hyperbilirubinemia was noted in 2 of the 3 patients, and a mildly prolonged prothrombin time was observed in one patient. No acute liver decompensation (i.e., ascites, hepatic encephalopathy, hepatorenal syndrome, or variceal bleeding) was reported. All 3 of these patients received the antiviral agent entecavir, which led to sustained viral suppression and smooth recovery with no complications. The time course of HBV reactivation is described below and shown in Fig. 2a–c and Table 2.

Table 2

Clinical features of RA patients who developed HBV reactivation during tocilizumab therapy

Data source	HBsAg+			HBsAg−/HBcAb+
	Case 1	Case 2	Case 3	Case 4
Age/sex	56/F	77/F	78/F	67/F
RA disease duration (year)	11	14	11	15
Duration of TCZ therapy (months)	5	6	8	18
HBsAg seroreversion	–	–	–	+
HBsAb	N	N	N	N
Anti-HCV	NA	NA	N	N
HBV DNA (peak, IU/mL)	3.7 × 107	1.6 × 107	1.7 × 108	2.5 × 107
ALT (initial/peak, U/L)	155/155	698/946	106/355	98/107
T.bil (initial/peak, mg/dL)	0.6/1.3	2.2/24.8	1.1/4.3	0.5/0.5
PT prolongation	N	N	Y	N
Ascites	N	N	N	N
Hepatic encephalopathy	N	N	N	N
Hepatitis flare-up	Y	Y	Y	N
Treatment for HBV reactivation	ETV 0.5 mg	ETV 0.5 mg	ETV 0.5 mg	ETV 0.5 mg
Outcome	Alive & well	Alive & well	Alive & well	Alive & well
Antirheumatic therapies before TCZ
bDMARDs (months)	ADA (14)	ETN (5)/rituximab (20)	ETN (46)/rituximab (13)	ETN (35)/ADA (25)/rituximab (25)/
sDMARDs	MTX/Pd/SSZ/CSA	MTX/Pd/SSZ/LEF/CSA	MTX/Pd/SSZ/LEF	MTX/Pd/SSZ/LEF
Concomitant immunosuppressants
MTX (mg/week)	0	7.5	7.5	7.5
Prednisolone equivalent dose (mg/day)	5	7.5	7.5	7.5
SDMARDs	N	SSZ	SSZ	SSZ

ETV, entecavir; IFX, infliximab; TAC, tacrolimus; RA, rheumatoid arthritis; HBV, hepatitis B virus; HCV, hepatitis C virus; F, female; TCZ, tocilizumab; HBsAg, HBV surface antigen; HBc Ab, HBV core antibody; ALT, alanine aminotransferase; IU, international units; T.bil, total bilirubin; PT, prothrombin time; sDMARDs, synthetic disease-modifying antirheumatic drugs; Pd, prednisolone; MTX, methotrexate; LEF, leflunomide; SSZ, sulfasalazine; CSA, cyclosporine, bDMARDs, biological disease-modifying antirheumatic drugs; ADA, adalimumab; ETN, etanercept; NA, not applicable; N, did not happen; Y, happened

Fig. 2

Time course of serum alanine aminotransferase and total bilirubin concentrations in patients experiencing HBV reactivation. Abbreviations: ALT, alanine aminotransferase; T.bil, total bilirubin; HBV, hepatitis B virus; HBsAg, HBV surface antigen; HBcAb, HBV core antibody; TCZ, tocilizumab; ETV, entecavir

Clinical Features of HBsAg−/HBcAb+ Patients with HBV Reactivation

The general characteristics of the HBsAg−/HBcAb+ patients are shown in Table 1. With TCZ administration, one HBsAg−/HBcAb+ patient (1/64; 1.6%) experienced HBV reactivation (Fig. 1; Table 2). In this case, after 18 months of TCZ treatment, HBsAg seroreversion with serum HBV DNA appearance (2.5 × 107 IU/mL) was observed. Her serum ALT level remained stable without evidence of hepatitis flare-up. Entecavir (0.5 mg/day) was initiated, and the HBV viral load was undetectable 22 months later. TCZ treatment was continued. The time course of HBV reactivation is described below and shown in Fig. 2d.

Discussion

Our results show that RA patients receiving TCZ are at risk of HBV reactivation. The risk was very high for HBsAg+ patients who were not administered an antiviral prophylactic agent (3/3; 100%). This risk was eliminated by antiviral prophylaxis. HBV reactivation in HBsAg+ patients often occurred within the first year of TCZ treatment (median administration time, 6 months; range, 5–8 months) and was associated with hepatitis flare-up. We also observed one case of HBV reactivation among HBsAg−/HBcAb+ patients (1/64; 1.6%).

Patients treated with TCZ are at risk of serious infections, including tuberculosis and other opportunistic bacterial, invasive fungal, and viral infections. The European Society of Clinical Microbiology and Infectious Diseases suggests that TCZ use puts patients at a modest risk of overall infection [16]. Because patients with HBV infection were excluded from pivotal TCZ trials [35, 36], the risk of HBV reactivation was not well reported.

Few studies with limited case numbers have investigated the risk of HBV reactivation among RA patients receiving TCZ treatment, especially in HBsAg+ patients without prophylactics (Supplement Table 1) [17–20, 22–31]. There have only been three studies, including 8 patients, on the HBV reactivation risk in HBsAg+ patients, with a reported reactivation rate ranging from 0 to 60% [17-19]. The study from Taiwan that investigated HBV reactivation in RA patients undergoing biological treatment included two HBsAg+ patients receiving TCZ, and both were free of reactivation [17]. Another study from Japan included only one HBsAg+ patient receiving TCZ, and no HBV reactivation was found [18]. A prospective study including 5 HBsAg+ RA patients receiving TCZ reported an HBV reactivation rate of 60% (3/5) [19]. In the current cohort, the highest HBV reactivation rate (100%) was noted. HBV reactivation was determined by the HBV serologic status [7, 37, 38], host immune status, treatment duration, glucocorticoid comedication [17], and history of bDMARD use [5, 39]. In the current study, all HBsAg+ patients underwent comedication with glucocorticoids and had a history of bDMARD use. These factors may explain the higher risk of HBV reactivation in our study. Without a suitable comparison population, the relationship of steroid and bDMARD treatment with HBV reactivation risk could not be observed in this study. Recently, tocilizumab with steroids has been applied in severe COVID-19 patients to reduce the cytokine storm [10, 40], and the risk of HBV reactivation needs to be considered. Our reports indeed strengthen the evidence of the high HBV reactivation risk of TCZ in this population. Combining those reports, the overall HBV reactivation rate was 55% (6/11) in HBsAg+ patients receiving TCZ (Supplement Table 1) [17–20, 22–31].

The early reactivation of HBV observed in our HBsAg+ patients during TCZ therapy is consistent with other reports (Supplemental Table 2) [19, 21]. A case study from the Netherlands reported that one HBsAg+ patient experienced HBV reactivation with fulminant hepatitis 2 weeks after a single dose of TCZ [21]. Although antiviral treatment was immediately administered, hepatic failure ensued, requiring liver transplantation [21]. A prospective study from China reported that HBV reactivation occurred 1–3 months after patients received 3 doses of TCZ, with none experiencing hepatitis flare-up. After antiviral treatment, all these patients recovered well. In our study, the median time to reactivation from the first TCZ dose was 6 months. All HBsAg+ patients with HBV reactivation developed hepatitis flare-up, and 2 even had hyperbilirubinemia. After entecavir treatment, we observed improvements in liver function and hyperbilirubinemia. These reports indicate a short interval between the first dose of TCZ and HBV reactivation (Supplemental Table 2) in HBsAg+ patients. The reactivation may result in fulminant hepatitis despite early preemptive treatment.

In contrast to the high rate of HBV reactivation in HBsAg+ patients without antiviral prophylaxis, none of the HBsAg+ patients who received antiviral prophylaxis experienced HBV reactivation in our study (Fig. 1). Only two studies have reported the effect of antiviral prophylaxis in HBsAg+ patients receiving TCZ [19, 20]. Those studies included 12 patients in total, and none of the patients developed HBV reactivation under antiviral prophylaxis. Our report increases the strength of the evidence of antiviral prophylaxis for HBsAg+ RA patients receiving TCZ (Supplement Table 1) [17-20]. Due to the high risk of HBV reactivation, short interval between TCZ administration and reactivation, and possibility of fulminant hepatitis, antiviral prophylactic agents should be given to HBsAg+ patients before TCZ therapy.

The reported rates of HBV reactivation among HBsAg−/HBcAb+ patients under TCZ treatment are inconsistent (Supplemental Table 1). [17–20, 22–31] A total of 11 studies have addressed the risk of HBV reactivation in HBsAg−/anti-HBc+ patients in small groups of patients (range, 4–48 patients) [19, 22–31]. The HBV reactivation rate ranged from 0 to 25%, and the overall HBV reactivation rate was 2.2% (5/232). Four Japanese studies reported a total of 5 cases of HBV reactivation among HBsAg−/HBcAb+ RA patients receiving TCZ (Supplemental Table 3) [18, 28–31]. The viral load fluctuated between undetectable and detectable in most cases, and the reactivation resolved spontaneously without antiviral treatment. Our cohort included 64 HBsAg−/HBcAb+ patients who received TCZ; among them, there was one patient with HBsAg seroreversion and serum HBV DNA elevation up to 2.5 × 107 IU/mL without hepatitis flare-up. This result indicates that HBsAg−/HBcAb+ patients are still at risk of HBV reactivation.

It should be noted that up to 26% of patients in this cohort received rituximab before tocilizumab therapy. Three of 4 HBV reactivation patients had a history of rituximab treatment. Rituximab therapy is thought to have a high risk of HBV reactivation by the AGA institute [7, 37]. However, studies on the HBV reactivation rate in rheumatic patients receiving rituximab are rare [38]. A previous study from Taiwan revealed that the incidence of HBV reactivation under rituximab treatment was up to 40% and 100% in HBsAg+ RA patients without or with steroid treatment [17]. Our previous report demonstrated that the incidence of HBV reactivation was up to 60% and 8% in HBsAg+ or HBsAg-/anti-HBc+ RA patients treated with rituximab [5]. According to the policy of National Health Insurance in Taiwan, RA patients with a poor response to rituximab should wait 6 months after the last dose of rituximab before switching to another biological agent. Although the time interval between rituximab and tocilizumab treatments was at least 6 months in our study, a history of rituximab treatment may still have some impact on HBV reactivation and is worthy of concern.

Similarly, a history of treatment with other bDMARDs may play a role in HBV reactivation. In the current cohort, all HBsAg+ patients and 70% of HBsAg-/anti-HBc+ patients had a history of bDMARD use. Schwaneck et al. noted that a history of treatment with three or more bDMARDs was present among more anti-HBc+ patients with than without reactivation (P = 0.017) [39]. Previous report from our group demonstrated that a history of TNF-alpha inhibitor use was associated with HBV reactivation in HBsAg-/anti-HBc+ patients receiving rituximab [5]. Because of the low number of reactivation cases and the high number of cases with a history of bDMARDs treatment, our study cannot clarify the association between previous biological use and HBV reactivation. However, the higher HBV reactivation rate in this study than in previous reports (Supplemental Table 1) may suggest the importance of previous bDMARDs exposure.

This study has several limitations. First, the retrospective, observational design may lead to missing data. Some data (such as the quantified HBsAg, HBeAg, anti-HBe, anti-HBs, and HBV DNA levels) were incomplete. Thus, using those markers to predict the HBV reaction is not possible in this study. However, our investigation indeed provides more evidence about HBV reactivation in RA patients receiving TCZ-containing treatment. Further prospective studies are necessary to address the predictive role of these HBV markers. Second, our study only enrolled Asian patients; whether our findings are applicable to other populations is uncertain.

Conclusion

Tocilizumab is indicated in RA and has the potential to reduce the cytokine storm in severe COVID-19 patients. However, tocilizumab treatment carries the risk of HBV reactivation. The risk in HBsAg+ patients is high, and it could be eliminated by antiviral prophylaxis. Although HBsAg−/HBcAb+ patients have a very low risk, monitoring HBV DNA and HBV markers remains necessary. A history of bDMARDs or steroid use and a dynamic HBV serologic status may influence the risk of HBV reactivation, and further study is necessary to conclude the association.

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