Abstract

Introduction: Hepatitis C virus (HCV) infection affects almost 180 million people around the world. Even though the development of direct acting antivirals (DAAs) has significantly improved the treatment responses to HCV infection, treatment with pegylated interferon (PegIFN) in combination with ribavirin is considered the standard of care (SOC) for chronic HCV infection treatment in countries with limited medical resources. Considering the inhibitory effect of vitamin B12 on HCV replication, we have evaluated the effect of vitamin B12 supplementation along with SOC on treatment outcomes in patients with chronic HCV infection, who were antiviral treatment-naive.


Methods: In this regard, seventy-four HCV-infected patients, naïve to antiviral therapy, were randomly assigned to receive SOC or SOC in addition to vitamin B12 (SOC + B12). Viral response was evaluated at 4, 12, 24 and 48 weeks following the initiation of viral treatment and at 24 weeks after completing the treatment. Genotyping of the interleukin 28B (IL28B) polymorphisms was also performed. Demographic characteristics, clinical findings, fibroscan results and drug adverse effects were recorded.


Results: Our findings showed that rapid viral response was not significantly different between the two groups; however, the rates of complete early viral response (cEVR) (p=0.033), end-of-treatment viral response (ETVR) (p=0.001) and sustained virologic response (SVR) (p=0.0001) were significantly higher in SOC + B12 patients compared to SOC patients. Besides, in SOC + B12 patients, those with a higher baseline viral load and carriers of IL28B CC genotype showed significantly higher rate of SVR.


Conclusion: In conclusion, the addition of vitamin B12 significantly improved the rate of SVR in HCV-infected patients, who were naïve to antiviral therapy. As this treatment regimen is safe and inexpensive, it proposes an option for improving the effectiveness of the HCV treatment with SOC, particularly in resource-limited settings.


 

Keywords: Hepatitis C virus Pegylated Interferon Ribavirin Vitamin B12


Introduction

Hepatitis C virus (HCV) is a leading cause of liver-related mortalities and morbidities and is a major health concern worldwide. With the emergence of approximately 3-4 million new cases of HCV infection every year, it is estimated that 2%-3% (130-170 million) of the world popula­tion are chronically infected 1. HCV transmission occurs principally via the exposure to contaminated blood or blood products. The most important mode of HCV transmission is needle sharing among intravenous (IV) drug users. Blood transfusion, tattooing, and sexual contacts are possible ways of spreading HCV infection 2. Although the infection is preliminary acute, about 75%-85% of infected patients fail to clear the virus within 6 months and gradually progress to chronic infection 3. Among chronically infected cases, 10%-20% of patients develop liver cirrhosis over a period of 20-30 years, and of those with cirrhosis, 1%-5% will develop hepatocellular carcinoma (HCC) annually. As a result, on a global scale, chronic HCV infection is responsible for approximately 250 000 to 350 000 deaths annually, which are mostly related to the decompensation of cirrhosis, end-stage liver disease, and HCC 4,5,6.

Diagnostic tests for HCV infection use serological assays to detect specific antibodies to HCV (anti-HCV) and molecular techniques to detect HCV-RNA in blood serum or plasma. A positive HCV antibody immunoassay test reveals an exposure to HCV; however, as patients who have spontaneously cleared the disease may produce false-positive anti-HCV results, it should be followed with a qualitative or quantitative polymerase chain reaction (PCR) test to detect the presence of HCV RNA in the blood 7,8.

Based on sequence homology analysis, at least seven major HCV genotypes and numerous distinct subtypes have been determined. Due to the genetic heterogeneity of HCV, evolution or existence of different HCV quasispecies in each patient, and the low efficient in vitro virus propagation, the development of HCV vaccine remains challenging.

The proximate goal of HCV treatment is viral eradication, which is achieved by eliminating detectable circulating HCV 6 months after treatment cessation. Between 2001 and 2011, standard treatment for chronic HCV infection was based on the use of PegIFN α-2a or 2b in combination with ribavirin, known as SOC. This treatment regimen yields an SVR in 40– 80% of cases depending on different viral and host parameters 9,10. The recently developed DAAs are consisting of protease inhibitors, NS5A inhibitors, nucleotide analog NS5B polymerase inhibitor and the non-nucleotide polymerase inhibitor 7,11,12,13. These new treatments improve SVR rates significantly in difficult cases such as genotype 1 HCV infection 13. Despite these advantages, in most of low- and middle income countries including Iran, access to these drugs is limited, mostly due to their high cost and unavailability 14. Population based epidemiological studies have estimated that the prevalence of HCV in the Iranian general population is less than 0.5%, which is relatively low 15. Among the infected patients with genotype 1a, 3a and 1b genotypes are known to be the most common genotypes 16,17,18. Available studies have showed that several host factors including host genotypes (race, age, gender, IL28B), degrees of hepatic fibrosis prior to treatment response and virological genotypes and RNA levels can be used to predict SVR rates.

HCV is an enveloped RNA virus belonging to the family Flaviviridae 19. The virus possesses an internal ribosomal entry site (IRES) at the 5′ untranslated region (UTR). The IRES is essential for the translation of viral polyprotein precursors. It is a complex RNA structure responsible for the correct assembling of ribosomal subunits at the viral start codons, which act through a mechanism that bypasses the canonical eukaryotic mRNA translation initiation. The unique structure and high sequence conservation of the 5′ UTR rendering IRES RNA represents a unique structure for drug targets.

Cobalamins, the class of compounds to which vitamin B12 belongs, are mostly stored in the human liver 20. Recent studies have reported that various liver diseases such as acute hepatitis, cirrhosis, HCC, and metastatic liver diseases are associated with major alterations in plasma vitamin B12 concentrations 21,22,23. Moreover, the results from an available in-vitro study have reported that vitamin B12 plays a natural role in the negative regulation of the HCV replication cycle 24. Based on these evidences, the possible role of vitamin B12 supplementation in improving the rates of viral response to antiviral therapy in HCV carriers has been investigated. Recently, vitamin B12 supplementation in HCV carriers showed a significant improvement in response to treatment with PegIFN and ribavirin at all time-points during therapy 25. However, this study was conducted on a limited number of patients and no clinical study has investigated the implication of adding B12 to SOC in the setting of HCV treatments. The aim of this randomized clinical trial was to assess the effect of vitamin B12 addition to SOC on the viral response to antiviral therapy in patients with naïve chronic HCV infection.

Methods

Subjects

Patients with chronic HCV infection and naïve to antiviral therapy were enrolled among those referred to the hepatology clinic of Rasoul-e-Akram university Hospital between 2014 and 2016. Patients either aged <18 or >65 years, with the history of treatment course with interferon and/or ribavirin, having conditions with consequences for liver disease, such as alcoholic liver disease, HBV or HIV infection, autoimmune hepatitis, HCC, decompensated cirrhosis, as well as severe synchronous disease or contraindications to treatment (depression, psychosis, epilepsy, uncontrolled hypertension, cytopenia (haemoglobin<12 g ⁄dL, leukocyte count <3000 ⁄mm3, platelet count <100 000 ⁄mm3), or having severe cardiac and pulmonary disease were excluded from the study. Written consent to participate in the study was obtained from all patients. The study protocol was approved by the ethic committee of the Iran University of Medical Sciences (ethic code: Approval date; 2015-04-15, 1394/01/26-Ethics committee No; 25592) and registered by the Iranian Registry Clinical Trial (IRCT Code: IRCT Id IRCT2015041720178N3).

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Figure 1 . Flow of patients according to treatment arm and HCV genotype.

Study assessments

After recording the baseline demographic data (Table 1), the following tests were performed for all patients: aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, complete blood cell count, total and direct bilirubin, albumin, prothrombin activity, C-reactive protein, thyroid functional test, fasting blood sugar, triglyceride, ferritin and cholesterol levels. Anti-HCV antibodies were detected by third generation enzyme-linked immunosorbent assay (Ortho. HCV Elisa Test System, Ortho Diagnostics), according to manufacture instruction. The presence of HCV-RNA in serum was determined by nested reverse transcription PCR (ROCHE; Roche Diagnostics GmbH, Roche Ap-plied Science, Mannheim, Germany). HCV genotype was identified by line-probe assay (INNO-LiPA TM HCV II, Belgium, Innogenetics) test. Evaluation of liver stiffness was measured by fibroscan in all cases using Fibroscan FS502 touch and CAP system (Manufacturer; Echosense, France). The levels of steatosis were graded as follows: 0 (absent), 1 (30% of hepatocytes affected), 2 (30-70% of hepatocytes affected) and 3 (>70% of hepatocytes affected).

Table 1.

Baseline demographic, imaging and laboratory data in both treatment groups

SOC + Vit B12 SOC P-value
Age (mean±SD) 44±12 41±10 NS
Sex (Male) n (%) 32(88% ) 33(85%) NS
HCV-Genotype n (%)
1a 19(52%) 20(52%) NS
1a 15(41%) 16(42%) NS
1a/b 1(2%) 1(2%) NS
1a/3a 1(2%) 1(2%) NS
Baseline-HCV load n (%)
>600000 U/L 9(25%) 10(29%) NS
<600000 U/L 27(75%) 28(71%) NS
Fibroscan; Steatosis score n (%)
0 14(38%) 10(26%) NS
1 8(22%) 15(39%) NS
2 4(11%) 5(13%) NS
3 10(27%) 8(21%) NS
Fibrooscan; Fibrosis score n (%)
0 12(33%) 15(39%) NS
1 10(27%) 9(23%) NS
2 9(25%) 10(26%) NS
3 2(5%) 2(5%) NS
4 3(8%) 2(5%) NS
AST (Mean±SD) 57±21 61±25 NS
ALT (Mean±SD) 79±37 76±35 NS
TG (Mean±SD) 101±61 113±51 NS
FBS (Mean±SD) 95±13 92±17 NS
Cholesterol (Mean±SD) 164±26 176±33 NS
Smoker n (%) 24(66% ) 25(66%) NS
Addiction (non-IV) n (%) 23(63%) 20(53%) NS
Alcohol user n (%) 21(58%) 23(60%) NS
BMI (Mean±SD) 24±4.79 24±3.90 NS
Platelet (Mean±SD) 193000±610000 211000±24000 NS
Hb (Mean±SD) 14±0.60 14±0.50 NS
Ferritin (Mean±SD ) 77±12 81±14 NS
CRP (Mean±SD ) 7±2 7±3 NS

The rs12979860 C/T polymorphism, located 3 kb upstream of the IL28b gene is known to have a powerful association in response to the treatment in HCV, where C allele is the favorable allele for predicting SVR 26. In this regard, we also performed genotyping of this polymorphism by PCR-based restriction fragment length polymorphism assay.

Subjects Randomization and Treatment Regimen

The participants were randomly assigned to one of the following treatment groups: PegIFN plus ribavirin and vitamin B12 (A group) or PegIFN plus ribavirin (B group). Randomization was carried out prior to the start of the trial using a computer-generated list prepared by a researcher not involved in the therapeutic regimes of patients, and unaware of patient characteristics except for the HCV genotype. PegIFNα2b (PegInteron,Shering –plough, Newjersy, USA) was used at a dosage of 1.5 mg/kg/week for all patients.

In patients infected with HCV genotype 1, ribavirin (Rebetol 200 mg hard capsule, Shering –plough, Newjersy, USA) was administered with a dosing based on body weight (1000 mg/day for patients weighing <75 kg, 1200 mg/day for patients weighing >75 kg); in the case of infection by genotype 2 or 3, a single ribavirin dose of 800 mg/day was administered. The treatment continued for 24 and 48 weeks for genotypes 3 and 1, respectively. Patients in the SOC+ B12 group received vitamin B12 at a dose of 5000 microgram by intramuscular injection every 4 weeks during the antiviral therapy.

Table 2.

Distribution of IL28B genotype between case and control groups

IL28B GENOTYPE SOC N (%) SOC + VITAMIN B12 N (%) P-value
3a- IL28B CT 10(26%) 8(22%) 0.89
3a- IL28B CC 10(26%) 9(24%) 0.75
3a- IL28B TT 2(5%) 2(5%) 0.99
1a- IL28B CC 6(15%) 8(22%) 0.77
1a- IL28B CT 5(13%) 3(8%) 0.52
1a- IL28B TT 3(7%) 3(8%) 0.9
1a/b- IL28B CT 1(2%) 2(5%) 0.1
1a/b- IL28B TT 1(2%) 1(1%) 0.98

Treatment Efficacy Assessments

The efficacy of treatment regimens was compared by viral response between two study groups. RVR was defined as a negative HCV RNA test at week 4 of treatment. Undetectable serum HCV-RNA at week 12 of treatment was defined as cEVR, whereas an ETVR was defined as undetectable HCV RNA at the end of the treatment. SVR was defined as undetectable serum HCV-RNA level at 24 weeks after cessation of antiviral therapy. The reappearance of HCV-RNA during treatment was defined as virological breakthrough. Patients who showed HCV-RNA rebound after achieving ETVR were considered as early ‘relapse’ and if it occurred after the achievement of SVR, they were defined as “late relapse’. Discontinuation of treatment due to adverse events was defined as dropout. Termination of treatment was assignable to patients who either did not obtain a declined serum HCV-RNA concentration at least 2 logs under baseline at week 12 or did not achieve clearance of serum HCV-RNA level after 24 weeks of treatment. Patients who assigned to treatment discontinuation were defined as ‘non-responders’.

Table 3.

Rates of rapid, early, end-of-treatment and sustained viral response in the two treatment groups

SOC SOC + Vit B12 P- value
RVR 30/38(78%) 29/36(80%) NS
Genotype (n %)
1 13/18(72%) 12/17 (70%) NS
3 17/20 ( 85 %) 17/19(89%) NS
Baseline HCV Load
>600000 7/10(70%) 7/9(77%) NS
<600000 23/28(82%) 21/27(78%) NS
cEVR (n %) 26/38(68%) 30/36(83%) 0.033
Genotype
1 10/18(56%) 11/17 (65%) NS
3 16/20(80%) 19/19(100%) NS
Baseline HCV Load
>600000 6/10(60%) 6/9(67%) 0.032
<600000 20/28(71%) 25/27(92%)
ETVR 26/38(68%) 30/36(83%) 0.001
Genotype
1 10/18(55%) 12/17(70%) 0.001
3 16/20(80%) 18/19(92%) 0. 001
Baseline HCV Load
>600000 6/10(60%) 6/9(67%) 0.0001
<600000 20/28(80%) 24/27(89%) 0.0001
SVR 25/38(68%) 29/36(80%) 0.0001
Genotype
1 9/18(50%) 11/17(65%) 0.001
3 16/20(80%) 18/19(95%) 0.0001
Baseline HCV Load
>600000 5/10(50%) 5/9(55%) 0.001
<600000 20/28 (71%) 24/27(89%) 0.001
Baseline Fibrosis (KPa)
< 9.6 25/21(84%) 24/29(83%) NS
≥9.6 4/25 (16%) 5/29(17%) NS
IL28B Genotyping
CC 14/25(56%) 17/29(58%) NS
TT 4/25(16%) 6/29(20%) NS
CT 7/25(28%) 6/29(20%) NS
Relapse 3/26(11%) 1/31(3%) 0.044
Breakthough 2/38(5%) 1/36(3%)
Drop out 6/38(16%) 1/36(3%) 0.001
Nonresponder 5/38(13%) 1/36(3%) 0.001

Dose modifications

The modifications of PEG-IFN and ribavirin doses during the course treatment were modified according to the AASLD guideline 27. Briefly, if neutrophil count decreased to ≤750/mm3 or the platelet count decreased to ≤50,000/mm3, the dosage of PEG-IFN was reduced by half. Discontinuation of PEG-IFN treatment was mandatory if the neutrophil count increased to ≤ 500/mm3 or the platelet count reduced to ≤ 25,000/mm3.

Table 4.

Comparison of Clinical and Laboratory Adverse Effects between Case and Control Groups

PegINF & RIBA N=38 PegINF & RIBA + Vit B12, N=36 P-value
Discontinuation 6/38(16%) 1/36(3%) 0.0001
Adverse effects (%) 24/38(63%) 20/36(55%) 0.0001
Dose modification 9/38(24%) 3/36(8%) 0.0001
Laboratory abnormality
Anemia
HB<10 6(16%) 2(5%) 0.001
HB<8.5 1(2%) 0 0.032
Neutropenia
<750 1(2%) 1(2%) NS
<500 0 0 NS
Thrombocytopenia
<50000 1(2%) 0 NS
<25000 0 0 NS
Fatigue 15(39%) 11(30%) 0.0001
Headache 12(31%) 8(22%) 0.001
Fever 4(10%) 1(2%) 0.037
Flu-like 9(23%) 5(13%) 0.0001
Arthralgia 12(31%) 9(25%) NS
Insomnia 4(10%) 3(8%) NS
Nausea 4(10%) 1(2%) 0.0001
Alopecia Areata 3(7%) 2(5%) NS
Generalized Hair Loss 13(34%) 7(19%) 0.0001
Irritability 4(10%) 2(5%) NS
Anorexia 6(15%) 6(16%) NS
Weight loss 4(10%) 1(2%) 0.002
Depression 13(34%) 10(27%) NS
Diarrhea 2(5%) 1(2%) NS
Irregular Menstruation 1(2%) 1(2%) NS
Thyroid dysfunction 1(2%) 0 NS

If haemoglobin levels reduced to ≤10 g/dL or if severe cough or intolerable itching occurred, the dosage of ribavirin was reduced to 200 mg decrements. Ribavirin treatment was discontinued if a reduction of haemoglobin level to ≤ 8.5 g/dL was observed.

Adherence to treatment was assessed based on patient self-reports during their monthly visit and at 12-week post-treatment according to the ‘80/80/80’ rule. Based on the percentage of PegIFN and ribavirin administered doses to the planned total dose and the percentage of duration of treatment to the planned duration, patients who received at least 80% of both medications for at least 80% of the total scheduled time were considered compliant.

Table 5.

Logistic regression analysis for host and viral factors that can predict the treatment outcomes in both treatment group

SVR (SCO +Vit B12) SE P value Exp (B) 95%CI
Lower Upper
Constant -4.820 0.927 0.023 0.052 _ _
IL28B-CC 1.871 0.857 0.009* 3.12 1.87 9.53
High Viral load 0.054 0.376 0.049* 2.26 1.32 5.43

Table 6.

Multivariate analysis for all factors that predict SVR achievement in SOC treatment

SVR (SOC group) SE P-value Exp(B) 95%CI
Lower Upper
Constant -5.621 0.873 0.002 0.38 _ _
IL28B-CC 3.51 0.685 0.001* 2.87 1.42 8.72

Follow-up

The first 4 weeks (weekly) after treatment initiation and monthly physical examination, complete blood counts were performed for patients. Moreover, the levels of serum HCV-RNA and ALT were measured at 4, 12, 48 and 72 weeks after antiviral therapy started. Autoimmune serologic markers and thyroid functional examinations were performed every 3 months. To minimize possible bias, laboratory findings were collected by staffs, who were unaware of the study hypothesis.

Statistical analysis

In this study, descriptive variables analysis was performed using a Chi-square test. Continuous variables were expressed as mean ± SD. Normal distribution of the variables was evaluated by the Kolmogorov Smirnov test. Frequencies were calculated for categorical variables. The Mann-Whitney rank sum test and/or the Kruskal-Wallis test were used to compare two or more than two groups of continuous variables. To examine quantitative variables, t-test was used for comparison in two groups and ANOVA test was used to compare variables in more than two groups. In order to independently determine the effect of each baseline variables (gender, age, body mass index, score of fibrosis, the score of steatosis, the level of baseline HCV-RNA, HCV genotype, dose adjustment and treatment discontinuation), a univariate analysis was performed.

After the conventional data were interpreted, a logistic regression analysis was carried out to evaluate the impact of potential predictors for SVR by using SVRs (yes/no) as dependent variables and selected variables at baseline as independent factors. A comparative evaluation was performed to determine the effects of the various factors on the OR to obtain the SVR; thus, Z scores were calculated for each factor and compared between groups. Statistical analysis of data was performed using the SPSS (PC V.22; SPSS Inc). The P-values of less than 0.05 were considered as statistically significant.

Table 7.

Multivariate analysis for all factors that predict SVR achievement in SOC treatment

SVR SE P-value Exp(B) 95%CI
Lower Upper
Constant -5.250 0.625 0.042 0.082 _ _
Interleukin (cc) 1.620 0.864 0.038 2.85 1.87 10.28
Grope (vit b12) 2.380 0.896 0.001 3.11 1.12 9.32

Results

Of the 90 chronically infected patients that referred to our hepatology clinic, 16 were excluded from the study for the following reasons: having the history of treatment with interferon ± ribavirin (n=6), concomitant hepatitis B virus infection (n=2), heavy alcohol consumption (n=1), HCC (n=1), severe depression (n=3), poorly controlled diabetes (n=1), and refused treatment (n=2). Thus, 74 eligible patients were randomly assigned to receive one of these treatment regimens: PegIFN in combination with ribavirin (SOC (or PegIFN in combination with ribavirin plus vitamin B12 injections (SOC + Vit B12).

Patient’s mean ages were respectively 44±12 and 41±10 years in SOC + Vit B12 and SOC grops. Majority of our patients were male in both groups. Dominant genotype of HCV was genotype 3 in both groups (A=19/36 and B=20/38). The treatment groups did not show significant differences regarding to demographic, laboratory, virological and fibroscan parameters (Table 1). The distributions of IL28B genotypes were not significantly different between the two treatment groups (Table 2).

Viral response during antiviral therapy, at the end of treatment and during 24 weeks follow-up was reported in Table 3. Using ITT analysis, our results showed that the rates of cEVR (88% vs. 68%, p=0.033), ETVR (83 % vs. 68%, p=0.001) and SVR (80% vs. 68%, p=0.0001) were significantly higher in group SOC + Vit B12 compared to group SOC. However, the rate of RVR in group SOC + Vit B12 and group SOC was not significantly different (78% vs. 77%, p=0.097). The relapse, drop out and non-responder rates were significantly lower in group SOC + Vit B12 compared to group SOC. Viral breakthrough rate was not significantly different between two treatment groups (Table 3). Adverse events (especially in Fatigue, Headache, Fever, Flu-like, Nausea, Generalized Hair Loss, and Weight loss) were significantly lower in group SOC + Vit B12 compared to group SOC (55% vs. 63% P=0.0001). The results of laboratory abnormality showed that, anemia was significantly lower in group treated with SOC + Vit B12 compared to group treated with SOC alone. Besides, necessitation of dose adjustment was significantly higher in group using SOC compared to group using SOC + Vit B12 (25% vs. 8%, P=0.0001). The dosage of PegIFN and/or ribavirin was respectively reduced in 9/38 (24%) and 3/36 (8%) patients in SOC and SOC + Vit B12 groups, mainly because of laboratory abnormalities (anaemia in SOC = 6 and A=2 cases, neutropenia in group SOC + Vit B12 =1 and SOC =1 cases and thrombocytopenia in group SOC = 1 case). Group SOC also showed significantly higher rate of treatment discontinuation compared to group SOC + Vit B12 (6/38 patients (16%) vs. 1/36 patients (2%), P = 0.0001). Treatment discontinuation was caused by severe anemia (1 case), severe headache (2 cases), severe flu-like symptom (1 case), major depression and weight loss (1 case), thyroid function test abnormality (1 case) in group SOC and irritability and insomnia (1 case) in group SOC + Vit B12 (Table 4). When baseline parameters of HCV genotype (1 or 3), viral load, fibrosis score and IL28B genotype (CC, TT and CT) were considered, the results of logistic regression analysis demonstrated that SVR rate was significantly higher in group SOC + Vit B12 patients who had higher viral count (>600,000 IU/ml) and IL28B CC genotype, and insignificantly higher in patients with HCV genotype 1 (Table 5).

Regarding multivariate analysis, adding vitamin B12 to treatment and genotype IL28B allele CC were considered as a prognostic factor to achieve SVR in this study (Table 6,Table 7).

Overall, the compliance with the 80/80/80 rule was > 50% and group SOC + Vit B12 was significantly more adherent to treatment regimen than group SOC (30/36 (83%) in group SOC + Vit B12 vs 26/38 (68%) in group SOC). The flow of patients according to treatment arm and HCV genotype throughout the study is summarized in figure 1 (Figure 1).

Discussion

For decades, PegIFN in combination with ribavirin was recommended as SOC for chronic hepatitis C virus infection 28. The rate of SVR in patients receiving this treatment regimen is indicated to be 40– 80%, depending on various baseline parameters, such as HCV genotype, IL28B polymorphisms, gender and HCV RNA levels 9. The introduction of DAAs has remarkably improved SVR rates in shorter duration of treatment, and with better tolerability in comparison to SOC. However, treatment with PegIFN in combination to RBV is still used in countries where DAAs are not available or are expensive. As only a fraction of patients with chronic hepatitis C infection would have access to such expensive therapies, optimizing efficacy of PegIFN and RBV combination therapy has become a research of interest over the past few years. For instance, available reports have showed that the addition of Sofosbuvir and vitamin D to the combination therapy with PegIFN plus Ribavirin can increase the rate of SVR among HCV-infected patients 29,30,31.

Direct inhibitory effects of vitamin B12 on HCV IRES-dependent translation have been indicated by experimental evidences almost two decades ago 24. Since then, several studies have reported the correlation between vitamin B12 and virological response of chronic hepatitis C infection receiving SOC 25,32,33. Considering these evidences, the aim of the current study was to evaluate the possible effects of adding vitamin B12 by injection (at a dose of 5000 microgram) to PegIFN and RBV combination therapy on the virological response in treatment-naive patients with chronic HCV.

Here we provide evidence that addition of vitamin B12 to SOC significantly improves the rate of virological response in chronically HCV infected patients. Our findings showed that patients who received vitamin B12 during therapy achieved significantly higher rates of cEVR, ETVR and SVR compared to patients receiving PegIFN and RBV alone. Moreover, relapse, drop out and non-responder rates were significantly lower in this group. Patients who received PegIFN and RBV along with vitamin B12 experienced a significantly lower frequency of treatment side effects compared to those who received PegIFN and RBV only. Besides, necessitation of dose adjustment and treatment discontinuation was lower in patients who received vitamin B12 together with PegIFN and RBV. Our findings showed that SVR rate was significantly higher in patients receiving PegIFN and RBV plus vitamin B12, who had high viral count >600,000 IU/ml and IL28B CC genotype. The association of rs12979860 (C/T) polymorphism with both spontaneous and treatment-induced HCV clearance has been indicated in different studies 34,35. Regarding multivariate analysis, our findings showed that adding vitamin B12 to treatment and genotype IL28B allele CC were prognostic factors to achieve SVR. The results of IL-28B genotyping in our patients did not show any significant differences in the distribution of IL-28B genotypes (C/C, C/T and T/T) between two treatment groups, indicating that the higher rate of SVR observed in SOC + B12 patients was not affected by IL-28B genotype.

Our findings were in agreement with the open-label pilot study by Rocco et al. 25, which reported that the addition of vitamin B12 to SOC significantly improved the rate of virological response in patients with chronic HCV infection. Accordingly, Rosenberg and Hagen 32, in their work showed that high levels of vitamin B12 in serum is favorable for achieving an ETVR in CHC patients treated with SOC. Contrary to these results, Mechie et al. 21 reported that patients with lower baseline levels of serum vitamin B12 (cut-off value of 570 ng/L) achieved higher rate of SVR compared to patients with vitamin B12 above the cut-off value. However, as the liver is the main physiological reservoir of human, and in hepatic diseases, the release of vitamin B12 is accrued due to hepatic necrosis. Thus, in these situations, the liver content of vitamin B12 was not necessarily correlated with the serum levels of vitamin B12.

Conclusions

In conclusion, our findings showed that the addition of vitamin B12 to SOC significantly improved the rates of treatment response in HCV-infected patients. We are aware that the main limitations of our study were the small number of patients and lack of a placebo arm. Moreover, patients were not blinded to taking vitamin B12 and their baseline serum levels of vitamin B12 were not measured. Thus, the results should be interpreted cautiously. However, our findings along with previous research indicate that the addition of vitamin B12 improves the rate of virological response in chronic hepatitis C patients. As this treatment regimen is safe and inexpensive, it represents a promising option for improving the effectiveness of the HCV treatment with SOC, particularly in resource-limited settings.

Abbreviations

cEVR : Complete Early Viral Response

DDA : Direct Acting Antivirals

ETVR : End-of-Treatment Viral Response

HCV : Hepatitis C virus

IL28B : Interleukin 28B

IRES : Internal Ribosomal Entry Site

PegIFN : Pegylated Interferon

PCR : Polymerase Chain Reaction

RVR : Rapid Early Viral Response

SOC : Standard of Care

SVR : Sustain Early Viral Response

UTR : Untranslated Region

Competing Interests

The authors declared no competing interests.

Authors' Contributions

Marjan Mokhtare, Ahmad Darvishi Zeidabadi, Mansour Bahardoust: developed the theory, carried out the experiment, performed the measurements, contributed to sample preparation.

Saeid Safari, Mitra Barati, Shahram, Agah, Mahsa Motavaf verified the analytical methods, contributed to the interpretation of the results, wrote the article.

All authors read and approved the final manuscript.

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