Invest Clin 66(2): 166 - 174, 2025 https://doi.org/10.54817/IC.v66n2a04
Corresponding author: Flor Helene Pujol. Laboratorio de Virología Molecular, CMBC, Instituto Venezolano de
Investigaciones Científicas (IVIC), Caracas, Venezuela. E-mail: fhpujol@gmail.com
Optimization of a real-time PCR assay
for hepatitis B virus load determination
in infected patients.
María Zulay Sulbarán, Yoneira Fabiola Sulbarán, Carmen Luisa Loureiro,
Héctor Rafael Rangel, Rossana Celeste Jaspe and Flor Helene Pujol
Laboratorio de Virología Molecular, CMBC, Instituto Venezolano de Investigaciones
Científicas (IVIC), Caracas, Venezuela.
Keywords: hepatitis B virus; viral load; optimization; qPCR; genotype.
Abstract. Hepatitis B virus (HBV) infection is a significant health problem
in the world, with around 294 million chronic carriers. Determination of viral
load is crucial for the monitoring and treatment follow-up of HBV-infected pa-
tients. In-house methods are economical alternatives for those settings where
HBV viral load determination might not be widely available commercially. Mo-
lecular diagnostic techniques need to take into account the variability of this
virus. The aim of this study was the evaluation and optimization of a real-time
PCR method for the determination of HBV load. After optimization, the in-
house assay evaluated in this study showed acceptable sensitivity and specific-
ity, allowing its use for monitoring patients in low-income settings.
Optimization of a real-time PCR assay for hepatitis B 167
Vol. 66(2): 166 - 174, 2025
Optimización de un ensayo de PCR en tiempo real para la
determinación de carga viral del virus de hepatitis B en
pacientes infectados.
Invest Clin 2025; 66 (2): 166 – 174
Palabras clave: virus de hepatitis B; carga viral; qPCR; optimización; genotipo.
Resumen. La infección por el virus de la hepatitis B (VHB) es un gran pro-
blema de salud en el mundo, con alrededor de 294 millones de portadores cró-
nicos. La determinación de la carga viral es de importancia crucial para el mo-
nitoreo y el seguimiento del tratamiento de los pacientes infectados por el VHB.
Los métodos propios son alternativas económicas para aquellos países donde la
determinación de la carga viral del VHB podría no estar ampliamente disponible
comercialmente. Las técnicas de diagnóstico molecular deben tener en cuenta la
variabilidad de este virus. El objetivo de este estudio fue la evaluación y optimiza-
ción de un método de PCR en tiempo real para la determinación de la carga del
VHB. La prueba propia analizada en este estudio mostró, después de la optimiza-
ción, una sensibilidad y especificidad satisfactorias, lo que permitió su uso para
el seguimiento de pacientes en comunidades de bajos ingresos.
Received: 10-03-2025 Accepted: 09-05-2025
INTRODUCTION
Around 294 million persons are chroni-
cally infected with the hepatitis B virus
(HBV) in the world 1. HBV chronic infec-
tion frequently leads to cirrhosis and hepa-
tocellular carcinoma (HCC), with at least
800,000 deaths each year 1. This infection is
highly endemic in Sub-Saharan Africa, Asia,
and Indigenous populations in the Americas
and Oceania 2,3.
HBV belongs to the Hepadnaviridae
family. It is a partially double-stranded DNA
virus of around 3200 bp. In addition to the
virus, viral-like particles also circulate, com-
posed exclusively of the HBV surface antigen
(HBsAg) within a non-infectious envelope 4.
Up to ten genotypes and several subgeno-
types have been described for HBV, with the
American genotypes being the most diver-
gent. The tenth HBV genotype J seems to be
a recombinant one, and only one sequence
is available 5.
A recombinant HBV vaccine has been
developed, based on the HBsAg 6. After more
than 30 years of worldwide vaccination, viral
infection and HCC incidence reduction have
been widely demonstrated 6,7. These mea-
sures have led the World Health Organization
(WHO) to propose a plan for hepatitis elimi-
nation by 2030 8. However, nearly 300 million
people remain chronically infected, and no ef-
fective treatment is currently available.
The functional cure of chronic hepatitis
B is defined as HBsAg loss after therapy, which
is rarely achieved with the current therapy.
Novel agents in development and preexisting
ones will probably bring the tools to approach
this goal 9. In the last WHO guidelines of
March 2024, HBV treatment is recommended
for all adults and adolescents (over 12 years
old) with chronic hepatitis B if:
168 Sulbarán et al.
Investigación Clínica 66(2): 2025
1. Evidence of significant fibrosis
2. HBV DNA viral loads above 2000 IU/mL
and ALT levels exceeding the upper li-
mit of the reference range
3. Or presence of coinfections, such as
HIV, hepatitis C, hepatitis D, or other
comorbidities 10.
The determination of the viral load is
then of crucial importance for confirma-
tion of viral replication and the monitoring
of chronically infected hepatitis B patients.
Several commercial assays are available to
assess this biomarker, based on real-time
PCR or transcription-mediated amplifica-
tion (TMA), in most of the laboratories from
high-income countries. However, this might
not be the case in some low-income coun-
tries 11.
In-house methods are economical al-
ternatives for those settings where HBV vi-
ral load determination might not be widely
available commercially. Molecular diagnos-
tic techniques need to take into account the
variability of this virus. Portilho et al.12 de-
veloped a real-time PCR to determine HBV
load. This study aimed to evaluate and op-
timize this real-time PCR method for deter-
mining HBV load.
MATERIALS AND METHODS
Sera from HBV-infected patients
This study was approved by the Bioethi-
cal Committee of IVIC (“Biología molecular
de virus de hepatitis y el Virus de la Inmuno-
deficiencia adquirida (VIH) en Venezuela”,
December 5, 2024). The sera of patients di-
agnosed with HBV infection, and who gave
informed consent, were kept at -70°C until
use. DNA was extracted from sera using the
QIAamp Viral DNA Mini Kit (Hilden, Germa-
ny) and used in all the other analyses.
HBV PCR and sequencing
Nested PCR was carried out using previ-
ously reported primers 58P-1100N and S6-
S3as 13. PCR-purified fragments were sent to
Macrogen Sequencing Service (Macrogen,
Korea) for sequencing. The phylogenetic
analysis was performed with MEGA11 soft-
ware 14.
Viral load determination
According to the manufacturer’s in-
structions, HBV viral load was determined
with Bosphore® Ultra HBV Quantitation/
Detection (Anatolia Geneworks®, Istanbul,
Turkey). This test has been used previously
by several groups 15-17.
In-house real-time PCR determination
Real-time PCR for HBV was performed
according to the protocol suggested by
Portilho et al. 12. Additionally, an anti-
sense modified primer was designed for
an optimized assay: 5’-GGCCAAAATTCG-
CAGTCCCCAACC-3’. Real-time PCR was run
in a final volume of 15 µL, containing 6 µL
of DNA, 1X PCR buffer, 1 mM MgCl2, 0.4mM
dNTP mixture, 0.23 µM of each primer and
probe, 1.75 U Platinum® Taq DNA Poly-
merase (Thermofisher, USA). The final con-
ditions for the optimized assay were: 95°C
for 10 minutes, then 40 cycles at 97°C for
30 seconds, 54°C for 90 seconds, and a hold
stage of 32°C for 60 seconds.
Statistical analysis
The correlation between the values of
HBV viral load determined by the commer-
cial assay and the in-house method was eval-
uated with the Pearson´s coefficient 18.
RESULTS
Serum samples from HBV-infected pa-
tients were analyzed by a commercial kit and
the in-house real-time PCR to evaluate the
performance of an in-house real-time PCR. A
total of nine sera (and dilutions of them for a
total of 14 samples tested) were tested, with
variable HBV loads: five sera were classified as
HBV genotype F3 (one not shown in the tree,
since the sequence was shorter, but it could
be classified as F3), and one each as genotype
A2, C2, F2, and F4 (Fig. 1).
Optimization of a real-time PCR assay for hepatitis B 169
Vol. 66(2): 166 - 174, 2025
A good agreement was found between
the commercial assay and the in-house
method for 9/14 samples, but with an over-
all low correlation of R2=0.47 (Fig. 2A). The
samples exhibiting the discrepant results be-
tween the two tests were derived from two
samples, corresponding to HBV genotype C2
and F3 isolates. When these samples were ex-
cluded, the correlation coefficient increased
to R2=0.98 (Fig. 2B).
Fig. 1. Phylogenetic tree of the HBV isolates tested in this study. The S gene is analyzed (559 nt). The evolu-
tionary history was inferred using the Maximum Likelihood method and the General Time Reversible
model14. The tree with the highest log likelihood (-2602.78) is shown. The percentage of trees in which
the associated taxa clustered is shown next to the branches. Initial tree(s) for the heuristic search were
obtained by applying the Neighbor-Joining method to a matrix of pairwise distances estimated using the
Maximum Composite Likelihood (MCL) approach. A discrete Gamma distribution was used to model
evolutionary rate differences among sites (4 categories (+G, parameter = 0.6597)). The rate variation
model allowed some sites to be evolutionarily invariable ([+I], 62.58% sites). The tree is drawn to scale,
with branch lengths measured in the number of substitutions per site. This analysis involved 45 nucleo-
tide sequences. Codon positions included were 1st+2nd+3rd+Noncoding. All positions with less than
80% site coverage were eliminated, i.e., fewer than 20% alignment gaps, missing data, and ambiguous
bases were allowed at any position (partial deletion option). Bootstrap values are shown in the branches
of the tree. The isolates are named by their genotype and GenBank accession number, except for the
ones from this study (n=8), which are shown in purple. An additional HBV isolate (B02023) was not
included in the tree since the shorter sequence could also be classified as genotype F3.
170 Sulbarán et al.
Investigación Clínica 66(2): 2025
An alignment of the sequences of the
HBV samples for which discrepant results
were observed is shown in Fig. 3. The align-
ment reveals multiple mismatches between
the antisense primer and several HBV iso-
lates, absent in the sequences without dis-
crepant results. The mismatches were pres-
ent, particularly in genotype C isolates.
A new antisense primer for an opti-
mized real-time PCR was designed (Fig. 3).
The complementarity of the three primers
(sense, the new antisense and the probe)
was evaluated in a total of 16516 sequences
from the HBV database 19, as shown in Table
1. The three primers showed high sequence
identity with the analyzed HBV sequences
from all the genotypes analyzed: for some
sequences, one or two internal mismatch-
es were observed, frequently at the 5´end.
These few mismatches per sequence (not at
the 3´ end of the primer) may not hamper
the adequate performance of the real-time
PCR. The probe also demonstrated satisfac-
tory performance. In general, the sequence
of this probe was well conserved among all
the isolates. The only exceptions might be
for the recombinant forms of HBV, for which
the mismatches were frequent, particularly
with the probe, and for some HBV genotype
C sequences.
Fig. 4 shows the correlation of the opti-
mized in-house real-time PCR with the com-
mercial assay. A strong correlation was ob-
served across all the tested samples, using
the new antisense primer, including discrep-
ant samples and their dilutions (R2=0.99,
Fig. 4).
Fig. 5 shows the performance of the in-
house test with HBV-positive and negative
samples. Most negative samples did not ex-
hibit any signal during the PCR process (40
cycles), although 1/20 negative samples had
a cycle threshold (Ct) value of 39.01. The de-
tection limit was fixed at 50 UI/mL (Ct value
around 35), which is acceptable for manag-
ing HBV-infected patients.
DISCUSSION
Hepatitis B is still a significant health
problem in Venezuela, even if vaccination
campaigns may have reduced the burden of
this disease, particularly in some indigenous
populations, where HBV infection remains
highly endemic 20. The most common HBV
genotype in Venezuela is F (F3, followed by
F2, and less frequently F1 and F4), followed
by HBV genotypes with worldwide distribu-
tion (A and D) and infrequently the HBV
Asian B and C, particularly these last ones in
immigrants 13,20. The samples from this study
included different subgenotypes circulating
in the country, and this diversity was impor-
tant to assess the performance, particularly
in terms of sensitivity, of the real-time PCR
test analyzed.
Fig. 2. Correlation between viral load determination with a commercial assay and the in-house method of Portilho et
al. 12. 2A. All the samples were tested. Green and open circles represent the dilution of a sample, as shown
in the filled green. Orange open circles represent dilution of a synthetic control (amplicon from sample
B4810, which is shown in filled orange). 2B. Correlation for samples without discordant results (orange and
purple in Fig. 2A, derived from B4810 and B5415, respectively) were omitted.
Optimization of a real-time PCR assay for hepatitis B 171
Vol. 66(2): 166 - 174, 2025
Fig. 3. Sequence alignment of the HBV preS region amplified by the in-house real-time test. Reference se-
quences are shown with their genotypes. The sequence of the samples used in this study is also inclu-
ded, except for B02023, since the sequence was shorter and does not cover the region. The primers
from Portilho et al. 12 for the in-house test are shown in blue. The new modified reverse primer is
shown in red. The reverse complement sequences are shown for the reverse primers.
Fig. 4. Correlation between viral load determination
with a commercial assay and the optimized
in-house method. Dilutions of the sample
B4810 (10–1, 10–3, and 10–4) are shown in
open orange circles, while sample 5379 and
its dilutions (10–1 and 10–2 open circles) are
shown in green.
Fig. 5. Performance of the optimized in-house re-
al-time PCR with sera from HBV-infected
patients or non-infected with this virus. Ct
values of positive (left, 38 samples) and ne-
gative (right, 20 samples) HBV samples. The
HBV negative samples were samples from six
HCV positive, three dengue virus positive,
two HIV-1 positive, 1 HAV positive, 1 HEV po-
sitive, and six with any known infecting virus.
172 Sulbarán et al.
Investigación Clínica 66(2): 2025
A low correlation was observed between
the commercial assay and the original in-
house primers proposed by Portilho et al. 12.
This finding contrasts with their analysis of
40 serum samples, where a good correlation
with the commercial assay was observed 12.
However, the authors did not mention the
genotype of their samples.
Although HBV is a DNA virus, it displays
a level of variability intermediate between
RNA and DNA viruses. The dependence of
a reverse transcriptase for its replication,
which lacks proof-reading activity, increases
the mutation rate of this virus. In contrast,
the highly compact genome (one of the
smallest animal DNA genomes), with a high
degree of overlap in the different open read-
ing frames, reduces the viability of some of
these mutations. The result is an intermedi-
ate mutation rate, compared to a DNA and
an RNA virus 20. The variability exhibited by
different HBV genotypes leads to differential
pathogenesis and variable resistance to IFN
treatment 21. In addition, the accuracy of
primers in PCR reactions is always limited.
In this study, analyzing more than
16,500 sequences to evaluate the suitability
of the new proposed primers suggests that
we can be confident in using those modified
primers. The only exception might be the re-
combinant isolates (and some genotype C iso-
lates), although we could not test any recom-
binant isolates. Recombination is a common
phenomenon in HBV 22,23. Infection with some
HBV genotypes has been associated with a
more severe disease and more rapid progres-
sion to HCC, for example, infection with HBV
genotype C: the relationship between HBV
recombinant genotypes and pathogenesis is
unknown at present 20,21. The recombinant
forms, in any case, may affect the sensitivity
of molecular diagnostic techniques.
Table 1. Complementarity of the primers used in the modified in-house method with HBV
sequences available in the HBV database.
HBV genotype N of sequences Sequences with divergence1
preSf preSr2 preSprobe
A 2359 104 48 64
B23534 246 64 68
C35088 386 1639 160
D43220 399 123 45
E5894 28 124 17
F5357 39 4 5
G687 2 0 0
H748 4 3 0
RF8929 237 134 287
Total (%) 16516 8.85% 12.95% 2.34%
1 The complementarity of the primers tested in the new in-house method were analyzed in the 16516 HBV sequen-
ces of the HBV database 19. Most of the observed divergences in the complementarity with the primers correspond
to only one or two internal mismatches. 2 For preSf and PreSr2, most of the sequences exhibited one mismatch at
the 5´end, so this first nt of the primer was not considered in the analysis. 3 Some mismatches were found in the
3´end of the primers: 38 sequences exhibited this mismatch for primer preSf, only 3 for preSr2. 4 One sequence
with a mismatch at the 3´end. 5 For preSf primer, most of the sequences exhibited one mismatch at the 5,7´end, so
this first nt was not considered in the analysis. 6 All the genotype G isolates have a T instead of an A in the fifth po-
sition of the primer preSr2, from 3´to 5´end, so this position was not considered in the analysis. 8 RF: recombinant
forms. Many sequences exhibited one or more mismatches, internal or at the 5´end.
Optimization of a real-time PCR assay for hepatitis B 173
Vol. 66(2): 166 - 174, 2025
In conclusion, modifying the HBVpreS
reverse primer significantly improved the
correlation of the viral load determination
by the in-house method, with the commer-
cial assay, increasing then the performance
of this test. The new version of the in-house
test displayed a satisfactory sensitivity and
specificity, allowing its use for monitoring
patients in low-income settings. A limitation
of this study is the relatively low number of
samples evaluated by the commercial as-
say and the in-house test. The in-house test
tested a higher number of samples (n=38
positive samples, and 20 negative, the last
ones without any signal). In addition, the in
silico validation of the assay with more than
16,000 sequences makes us confident in the
performance of the optimized test.
ACKNOWLEDGMENTS
To the health personnel who effective-
ly attended to the cases of hepatitis in this
study.
Funding
The Ministerio del Poder Popular para
Ciencia y Tecnología de Venezuela (MinCyT)
financed this project, Proyecto Mujer 2024.
Declaration of conflicts of interest
The authors declare that they have no
conflict of interest.
Number ORCID of authors
• María Zulay Sulbarán (MZS):
0009-0008-9798-5593
• Yoneira Sulbaran (YS):
0000-0002-3170-353X
• Rossana C Jaspe (RCJ):
0000-0002-4816-1378
• Carmen L. Loureiro (CLL):
0000-0003-3665-1107
• Héctor R Rangel (HRR):
0000-0001-5937-9690
• Flor H. Pujol (FHP):
0000-0001-6086-6883
Participation of authors
MZS, YS, RJC, CL, FHP: Substantial
contribution to the conception and design
of the study; data collection or their analysis
and interpretation, critical review of the ar-
ticle and approval of the final versión to be
published. HRR: critical review of the article
and approval of the final versión to be pub-
lished.
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