R E S E A R CH A R T I C L E

The performance of hepatitis C virus (HCV) antibody
point-of-care tests on oral fluid or whole blood and dried blood
spot testing for HCV serology and viral load among individuals
at higher risk for HCV in South Africa

Nishi Prabdial-Sing1,2 | Lucinda Gaelejwe1,2 | Lillian Makhathini1 |

Jayendrie Thaver1 | Morubula Jack Manamela1 | Susan Malfeld1 |

C. Wendy Spearman3 | Mark Sonderup3 | Andrew Scheibe4,5 | Katherine Young4 |

Harry Hausler4 | Adrian J. Puren1,2

1Centre for Vaccines and Immunology,

National Institute for Communicable Diseases,

Johannesburg, South Africa

2Faculty of Health Sciences, University of

Witwatersrand, Johannesburg, South Africa

3Division of Hepatology, Department of

Medicine, Faculty of Health Sciences,

University of Cape Town, Cape Town,

South Africa

4TB HIV Care, Cape Town, South Africa

5Department of Family Medicine, University of

Pretoria, Pretoria, South Africa

Correspondence

Nishi Prabdial-Sing, Centre for Vaccines and

Immunology, National Institute for

Communicable Diseases, Johannesburg,

South Africa.

Email: niship@nicd.ac.za

Funding information

Bristol-Myers Squibb Foundation, Grant/

Award Number: GRANT 95738_93649

Abstract

Background and Aims: To enhance screening and diagnosis in those at-risk of hepati-

tis C virus (HCV), efficient and improved sampling and testing is required. We investi-

gated the performance of point-of-care (POC) tests and dried blood spots (DBS) for

HCV antibody and HCV RNA quantification in individuals at higher risk for HCV (peo-

ple who use and inject drugs, sex workers and men who have sex with men) in seven

South African cities.

Methods: Samples were screened on the OraQuick HCV POC test (471 whole blood

and 218 oral fluid); 218 whole blood and DBS paired samples were evaluated on the

ARCHITECT HCV antibody (Abbott) and HCV viral load (COBAS Ampliprep/COBAS

TaqMan version 2) assays. For HCV RNA quantification, 107 dB were analyzed with

and without normalization coefficients.

Results: POC on either whole blood or oral fluid showed an overall sensitivity of

98.5% (95% CI 97.4-99.5), specificity of 98.2% (95% CI 98.8-100) and accuracy of

98.4% (95% CI 96.5-99.3). On the antibody immunoassay, DBS showed a sensitivity

of 96.0% (95% CI 93.4-98.6), specificity of 97% (95% CI 94.8-99.3) and accuracy of

96.3% (95% CI 93.8-98.8). A strong correlation (R2 = 0.90) between viral load mea-

surements for DBS and plasma samples was observed. After normalization, DBS viral

load results showed an improved bias from 0.5 to 0.16 log10 IU/mL.

Conclusion: The POC test performed sufficiently well to be used for HCV screening

in at-risk populations. DBS for diagnosis and quantification was accurate and should

be considered as an alternative sample to test. POC and DBS can help scale up hepa-

titis services in the country, in light of our elimination goals.

K E YWORD S

dried blood spot, HCV, high risk, point-of-care, screening

Received: 9 September 2020 Revised: 10 November 2020 Accepted: 4 December 2020

DOI: 10.1002/hsr2.229

This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any

medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

© 2021 The Authors. Health Science Reports published by Wiley Periodicals LLC.

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https://doi.org/10.1002/hsr2.229

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1 | INTRODUCTION

Globally, an estimated 71 million people have chronic hepatitis C,

accounting for almost 400 000 annual deaths.1 Hepatitis C virus

(HCV) is efficiently transmitted through blood.2 Groups of people at

high risk of acquiring HCV infection include people who inject/use

drugs (PWID/UD), men who have sex with men (MSM), sex workers

(SW), prisoners and healthcare workers.3 In the era of direct acting

antivirals (DAAs), short courses of all-oral therapy can be used to cure

most cases of HCV infection.4

Although data is limited, HCV seroprevalence in PWIDs is around

22% across sub-Saharan Africa3; 11% to 55% in Central Africa; 2% to

38% in West Africa and 1% to 65% in Southern and East Africa.5 In

Kenya, HCV prevalence in high risk groups is 7%6 while in Tanzania,

PWID have documented HCV seroprevalences of 28%7 and 50%8 and

MSM, 14%.9 In South Africa, a high HCV seroprevalence (55%) and

viraemic prevalence (43%) was reported in PWID in three major cities.10

Screening for HCV among people engaged in criminalized or stigmatized

practices can be challenging. Fear and experienced stigmatization by

healthcare workers of PWID/UD as well as the inadequacy of services

to meet their needs are barriers to HCV screening.11,12

Furthermore, HCV diagnosis requires confirmation of antibody

positivity by nucleic acid confirmatory testing (qualitative or quantita-

tive).13-15 In sub-Saharan Africa (SSA), the use of anti-HCV POC is

increasing as more research is focused on viral hepatitis.16,17 How-

ever, dried blood spot (DBS) testing and the uptake of anti-HCV POC

for diagnostics has been slow as innovative diagnostic methods

focused on priority diseases, such as HIV and TB18 in SSA. Currently,

whole blood is still being transported to centralized laboratories for

HCV antibody and then confirmatory HCV RNA testing. A cold chain

is to be maintained throughout the blood transport process and

should reach the testing laboratory within 48 hours.19 For HCV RNA

testing, blood is collected in ethylene-diamine tetra-acetate (EDTA)

tubes20 to avoid hemolysis and maintain RNA integrity,21,22 for opti-

mal RNA amplification. Moreover, whole blood requires centrifugation

for plasma/serum separation before testing. With centralized labora-

tory testing, inherent and unavoidable delays in process adversely

affect linkage to care and treatment initiation.23

More affordable options with less invasive sampling methods and

time to results, require evaluation, especially in lower-and-middle income

countries (LMICs) where HCV prevalence is unknown, populations are

hard to reach and centralized laboratory infrastructure varies.18 POC anti-

HCV tests, such as the OraQuick HCV test and SD Bioline HCV have

shown high sensitivities and specificities in recent years.24-26 Of the

Khuroo et al25 meta-analysis, four studies looked at assessing OraQuick

to a reference standard assay, with none of the studies from Africa.

In SSA, there are many remote regions with poor access to laborato-

ries and the use of DBS in these areas can be practical for screening and

diagnosis as DBS can be easily transported from distant areas to central-

ized laboratories.14 DBS sampling is less invasive (heel-finger-earlobe-

prick) compared to venous needle insertion27 and this can aid in sam-

pling where venous access is challenging. Considering that blood spot-

ting can be less painful than venipuncture, more people may be willing

to test. However, collection of proper quality and volume of blood onto

spots requires practice and training27 and it is for this reason that most

performance studies opt for precise aliquots of blood by using pipettes

to transfer venous whole blood onto filter cards.28,29 Still, comparative

quantitative results on capillary vs venous whole blood for HCV30 and

HIV31 were reported. Of the 18 studies on DBS for anti-HCV testing32

and 15 studies on HCV-RNA using DBS,33 none of the performance

studies were from Africa. To address the limited knowledge on POC and

DBS in SSA and to help scale up hepatitis services in our country, we

have investigated the performance of anti-HCV POC testing and the use

of DBS as an alternative sample matrix to that of plasma for HCV anti-

body and viral load testing.

2 | METHODS AND MATERIALS

2.1 | Study setting

This was a cross-sectional study that was integrated into existing HIV

testing, prevention and sexual health services provided by community-

based implementing sites for high risk populations. The larger study has

been well-described in “Hepatitis C within key populations across seven

cities in South Africa study.”34 The parent study conveniently sampled

people from high risk population groups from Cape Town (SWs, MSM,

PWID/UD), Durban (SWs, PWID/UD), Pietermaritzburg (SWs), Mthatha

(SWs), Port Elizabeth (SWs), Johannesburg (MSM) and Pretoria (MSM

and PWID/UD). Participants were recruited from mobile and

community-based health services targeting people at high risk for, or liv-

ing with HIV. Participants were tested for HBV surface antigen (HBsAg),

HCV (antibody, viral load and genotype) and HIV antibody (unless with

documentation of existing HIV infection).

In Cape Town, the city with the proposed largest sample size in

the larger study,34 anti-HCV POC testing was done using oral fluid,

and DBS testing. In the other cities, anti-HCV POC testing was done

using whole blood, without DBS testing. The selection of testing

modalities was based on available funding and human resources.

To avoid repeated blood draws, sufficient whole blood was drawn

from all participants for blood related testing that may have been

needed for rapid or other confirmatory testing.

2.2 | Sample

In total, 3439 participants (1528 SWs, 746 MSM, 1165 PWID/UD)

were enrolled in the larger study between August 2016 and October

2017.34 To validate the anti-HCV POC results (oral and blood samples)

and evaluate the DBS, venous blood samples were sent to the reference

laboratory, National Institute for Communicable Diseases (NICD, Johan-

nesburg) for laboratory testing. Furthermore, a subset of samples (blood

and DBS) negative for anti-HCV POC were also sent to the laboratory.

Sample size calculations were based on the formula [DEFF × Np

(1 − p)]/[(d2/Z21 − α/2 × (N − 1) + p × (1 − p)]35 using an 8% preva-

lence36 and precision of 4%. For anti-HCV POC, based on a

2 of 11 PRABDIAL-SING ET AL.



population of 2450 from all sites except Cape Town (the number of

participants expected to be recruited across cities where anti-HCV

POC testing would be done on blood), the sample size needed was

110 POC negative samples; equating to every 22nd negative POC

test per site (2450/110 = 22).

For the DBS evaluation, using the same formula as above, and

based on a population size of 1050 from Cape Town sites (the number

of high risk people anticipated to be recruited in the city as part of the

larger study), a sample size of 103 was calculated and every 10th neg-

ative POC test (1050/103 = 10) was sent to the laboratory.

2.3 | Blood collection, point-of-care testing and
DBS preparation

Whole blood specimens were collected once from each participant by

venipuncture in EDTA-treated vacutainers. The anti-HCV POC

(OraQuick HCV Rapid Antibody Test) was performed on site by

trained nurses as per manufacturer's instructions (OraQuick HCV

Rapid Antibody Test, OraSure Technologies, Bethlehem, Pennsylva-

nia). Whole blood samples were used on the OraQuick HCV Rapid

Antibody Test in all cities except Cape Town. Venipuncture whole

blood was collected using the specimen loop provided in the test kit.

In Cape Town, oral fluid samples were collected using the sample pad

provided in the test kit. The blood or oral fluid sampler was trans-

ferred into the developer solution and the test result was read

between 20 and 40 minutes as per manufacturer's instructions.

DBS samples were prepared by spotting 50 μL of whole blood

from the EDTA tubes onto each of the five circles on a Whatman-903

perforated protein saver card (GE Healthcare, Piscataway, New Jersey).

DBS cards were dried and packed in nonpermeable, plastic sealable

bags with two desiccant sachets and a humidity indicator card.

2.4 | Blood and DBS transport and receipt

All blood sample tubes and DBS cards were linked with a unique par-

ticipant identification code and transported to the NICD. Blood tubes

and DBS cards were stored at 4-8�C at the sites prior to shipping to

the laboratory. For the convenience of transport, blood tubes and

DBS were transported in sealed foil-lined cooler boxes with frozen

ice-packs. At the laboratory, whole blood from EDTA tubes were cen-

trifuged at 3000 rpm for 10 minutes at room temperature. The plasma

was transferred into 1.5 mL microtubes and stored at −70�C until

testing. DBS cards were stored at 4 to 8�C until testing.

3 | LABORATORY TESTING

3.1 | Antibody testing

The ARCHITECT HCV antibody assay was performed on the rec-

ommended volume of 70 μL plasma using the automated ARCHITECT

i1000SR CMIA system (Abbott Laboratories, Diagnostics Division, Abbott

Park, Illinois). For DBS samples from Cape Town sites, one spot (50 μL)

from the DBS card (GE Healthcare, Piscataway, New Jersey) was eluted

in 400 μL (Gavin Cloherty, Abbott diagnostics, personal communication)

of 1X PBS buffer (Lonza, Belgium) and 0.05% of Tween 20 (Merck,

Germany).37 The DBS were incubated at room temperature with continu-

ous agitation at maximum speed 300 motions per minute for 1 hour. A

volume of the DBS eluate (70 μL) was processed on the ARCHITECT

i1000SR system following manufacturer's instructions (Abbott Laborato-

ries, Diagnostics Division, Abbott Park, Illinois). For plasma and DBS, the

signal to cut-off ratios as indicated by the manufacturer, were used.

3.2 | Viral load testing

The COBAS Ampliprep/ COBAS TaqMan version 2 (CAP/CTM) assay

(Roche Molecular Systems, Pleasanton, California) was used to measure

HCV viral load on plasma. Plasma (700 μL) was vortexed for 10 seconds

(Heidolph, Reax Top, Germany) before processing on the CAP/CTM

assay. To prevent unequal spread of blood owing to variable hematocrit

levels, the whole perforated spot on the DBS card was used. Two DBS

spots were eluted in 1.0 mL of sample pre-extraction (Spex) buffer

(Roche Molecular Systems, Pleasanton, California). The tubes containing

the DBS in buffer were incubated on a dry and cooling heating block

Eppendorf Thermomixer R (Sigma, South Africa), at 56�C with continuous

shaking for 10 minutes (Roche Molecular Systems, Pleasanton, Califor-

nia).38 To quantify HCV on DBS, 700 μL of DBS eluate was tested using

the CAP/CTM assay (Roche Molecular Systems, Pleasanton, California).

To calculate the normalization coefficient, we had to account for

the 50 μL of whole blood that was spotted onto the Whatman

903 card. Two circles of DBS were used for viral load analysis in a vol-

ume of 1000 μL of SPEX buffer, providing a total volume of 1100 μL.

50% volume of plasma in DBS was assumed. Thus, 2 × 50 μL of whole

blood × 50% (100 μL × 50% = 50 μL of plasma). The normalization

coefficient was calculated to be 22. This was obtained by dividing the

total volume (whole blood and SPEX buffer) by the whole blood vol-

ume on each Wattman 903 card (1100 μL/50 μL = 22).

For plasma and DBS, the threshold value was set at the manufac-

turer's lower and upper detection limits which corresponded to

15 IU/mL and > 1.00E+08 IU/mL, respectively. On the CAP/CTM

assay, any result lower than the lower detection limit (LDL) of 15 IU/

mL was reported as LDL and any result where virus was not detected

was reported as “target not detected” (TND).

3.3 | Statistical analysis

As per the Standards for Reporting of Diagnostic Accuracy Studies

(STARD),39 the performance of POC and DBS was calculated by sensitiv-

ity, specificity, negative predictive value (NPV), positive predictive value

(PPV) and accuracy (Microsoft Excel 2016, Microsoft, Washington). Accu-

racy was the measure of agreement between the POC test and the labo-

ratory reference immunoassay and also between the sampling matrices.

PRABDIAL-SING ET AL. 3 of 11



DBS viral load results were compared to the plasma (reference

sample type) viral load results. Descriptive statistics using Microsoft

Excel 2016 (Microsoft, Washington) were reported as the means,

medians and interquartile ranges, with the minimum and maximum

ranges for plasma and DBS viral load, respectively. All quantitative

analyses were performed in log10-transformed values in international

unit/ml (IU/mL). A normalization coefficient was calculated and

applied to the raw DBS results before analyses to account for volume

difference and sample type in the DBS (Ed Marins, Roche Molecular

systems, California, personal communication).40

Sensitivity of DBS on the CAP/CTM assay was calculated as the

number of true positives (viral load ≥15 IU/mL) for DBS in relation to

plasma samples that had viral load ≥15 IU/mL. Specificity was calcu-

lated as the number of true negatives (virus not detected) on both

DBS and plasma samples.

The linear regression analysis was performed to determine the cor-

relation of DBS and plasma viral loads. The Bland-Altman analysis was

performed to determine the agreement between the DBS and plasma,

using the mean difference between the plasma and DBS viral load

values and the average viral load between plasma and DBS. All tests of

statistical significance were two-sided with an alpha value of .05.

3.4 | Ethics

The study protocol for the larger study was approved by the Univer-

sity of Witwatersrand Human Research Ethics Committee (WITS

HREC, M160510), Human Research Ethics Committee of the Univer-

sity of Cape Town (ref: 004/2016) and relevant provincial research

ethics committees. For this nested study, ethics approval was received

from WITS HREC (M170698). All participants provided written con-

sent to participate in the study. No remuneration was provided. The

data analyses for the patient group were performed on de-

identified data.

4 | RESULTS

4.1 | POC results

Of the 714 blood sample received at the laboratory, 16 were

deemed ineligible, due to repeat recruitment or no records of POC.

Of the 698 received samples that were eligible for testing, an addi-

tional eight samples hemolysis during transport and one DBS sam-

ple without a blood pair were excluded from the analyses (Figure 1).

Of the total of 689 samples analyzed, anti-HCV POC was per-

formed on 471 whole blood samples and 218 on oral fluid samples

(Figure 1). PWID/UDs accounted for 523, MSM for 70 and SWs for

96 (Table 1). A total of 516 participants were positive by anti-HCV

POC positive. The highest POC positivity was recorded for PWID/

UDs (N = 494, Table 1). In total, 147 participants had HCV and HIV

co-infection as detected on POC and of this, PWID/UDs accounted

for 138 (Table 1).

4.2 | Anti-HCV POC compared to the reference
laboratory immunoassay

4.2.1 | Whole blood POC

Of the 471 tested on whole blood POC, 370 were found to be posi-

tive (Table 2). Four false-negative results were found, of which one

sample had co-infection with HIV. Viral load was detected on three of

four samples and ranged from 4 to 6 log10 IU/mL. All three samples

were HCV genotype 1a. The three samples were received from sites

in different provinces.

4.2.2 | Oral fluid POC

Of the 218 oral fluid samples tested by POC, 146 were positive

(Table 2), with PWID/UDs accounting for 130 (Table 1). Of the four

false-negative results, none were HIV infected. Viral load was

detected on two of the four samples, with 5 and 7 log10 IU/mL,

respectively. One sample was genotype 1a, the other 3a. Of the four

samples, two were tested by the same field operator and all samples

were from the same site. There was no significant association with

serum HCV antibody titer (as measured by signal/cutoff [S/CO]

values) of false-negative result on either whole blood or oral fluid

POC compared to the true positives (11.5 S/CO vs 14.0 S/CO).

When POC results on either whole blood or oral fluid were compared

to plasma antibody results, the accuracy was 98.4% (95% CI 96.5-99.3)

(Table 2). Both sample types (whole blood and oral fluid) on POC testing

performed comparably, with high kappa values of 0.96 (Table 2).

4.3 | Anti-HCV DBS compared to plasma
on the reference laboratory immunoassay

A total of 218 paired DBS and whole blood samples were tested for HCV

antibody. An accuracy of 96.3% (95%CI 93.8-98.8), sensitivity of 96%

(95%CI 93.4-98.6) and specificity of 97% (95%CI 94.8-99.3) was calcu-

lated (Table 3). There were six false-negatives on DBS serology. Of these

six samples, two plasma pairs had detectable virus (viral load of 5 and

7 log10 IU/mL, respectively); two plasma pairs were TND; one plasma

pair had an LDL, and one had insufficient plasma for viral load testing.

4.3.1 | HCV viral load DBS compared to plasma
on reference quantitative assay

Of the 144 antibody positive concordant pairs, 142 were tested on

the CAP/CTM assay (Figure 1). Two samples had insufficient plasma

for additional testing. A total of 107 samples were positive with a

plasma viral load of ≥15 IU/mL and were compared to DBS of

≥15 IU/mL (Table 4). There were six DBS samples that produced dis-

cordant results (Table 4), with two LDL and four TND. All six samples

had plasma viral load of ≤100 IU/mL (2 log10 IU/mL). Sensitivity and

4 of 11 PRABDIAL-SING ET AL.



percentage concordance was calculated on 142 dB/plasma pairs.

Overall, a sensitivity of 107/113 (94.7%, 95%CI 91-98.4) and specific-

ity of 100% was calculated (Table 4). If we consider a cut-off value of

≥100 IU/mL for HCV RNA on plasma, then sensitivity on DBS would

be 100%.

For the 107 plasma samples, HCV viral load ranged from 1.17

to 7.13 log10 IU/mL, with a median of 5.42 ± 1.06 log10 IU/mL (IQR

4.84, 5.98). The median viral load on DBS, before normalization,

was 4.87 ± 0.94 log10 IU/mL (IQR, 4.34, 5.41) and the quantitive

range was 2.17 to 6.36 log10 IU/mL. After normalization, the

median viral load was higher at 5.21 ± 0.94 log10 IU/mL (IQR, 4.68,

5.75) and viral load ranged from 2.51 to 6.70 log10 IU/mL. The

mean titer difference between DBS and plasma before normaliza-

tion was 0.5 log10 IU/mL and after normalization, improved to

0.16 log10 IU/mL.

4.4 | HCV viral load correlation between DBS
and plasma

Correlation between DBS and plasma shows a positive linear relation-

ship with a Pearson's correlation coefficient of R = 0.94. A coefficient

of determination, R2 of 0.90 (P < .0001) for both linear regression cur-

ves with and without normalization was calculated (Figure 2A,B).

F IGURE 1 Flow diagram
indicating the number of sample
sets from collection to testing and
analyses

PRABDIAL-SING ET AL. 5 of 11



4.4.1 | HCV viral load agreement between DBS
and plasma

The Bland-Altman analysis on DBS viral load without applica-

tion of the normalization coefficient found a mean difference

(bias) of 0.50 ± (SD) 0.37 (95%CI 0.43-0.58). The limits of

agreement before normalization was found to be −0.23 to 1.24

(Figure 3A). The 95% CI for lower limit of agreement was

−0.35 to −0.11, and for upper limit of agreement was 1.11 to

1.36 (Figure 3A).

After application of the normalization coefficient to raw DBS viral

load values, a mean difference (bias) of 0.16 ± (SD) 0.37 (95% CI

0.09-0.23). This bias was a 5-fold improvement compared to bias

without correction. The limits of agreement after normalization was

found to be −0.57 to 0.89 (Figure 3B). The 95% CI for lower limit of

agreement was −0.69 to −0.45, and for upper limit of agreement was

0.77 to 1.02.

TABLE 1 Demographics on 689 participants

PWID/UD MSM SWs Total

No. per risk group 523 70 96 689

Male 454 69 6 529

Female 69 0 89 158

Transgender 0 1 1 2

Median age in years (IQR) 30 (26-35) 32 (26-40) 29 (25-36)

Anti-HCV POC positive 494 21 1 516

Whole blood 364 5 1 370

Oral fluid 130 16 0 146

Log viral load in IU/mL (IQR) 5 (5-6) 6 (5-6) NA

Co-infection HCV/HIV 138 9 0 147

Abbreviations: HCV, hepatitis C virus; IQR, interquartile range; MSM, men who have sex with men; POC, point-of-care; PWID/UD, people who injecting

drugs/use drugs; SWs, sex workers.

TABLE 2 Performance
characteristics of the OraQuick anti-HCV
POC on whole blood or oral fluid

Anti-HCV POC

Anti-HCV immunassay—Laboratory reference test

WB or OF WB OF

Pos Neg Total Pos Neg Total Pos Neg Total

Pos 513 3 516 367 3 370 146 0 146

Neg 8 165 173 4 97 101 4 68 72

Total 521 168 689 371 100 471 150 68 218

Sensitivity (%, 95% CI) 98.5 (97.4-99.5) 98.9 (97.9-99.9) 97.3 (95.2-99.5)

Specificity (%, 95% CI) 98.2 (96.2-100) 97.0 (95.5-100) 100

PPV (%, 95% CI) 99.4 (98.8-100) 99.2 (98.3-100) 100

NPV (%, 95% CI) 98.2 (96.2-100) 96.0 (94.3-99.8) 94.4 (91.4-97.5)

Accuracy (%, 95% CI) 98.4 (96.5-99.3) 98.5 (97.4-99.6) 98.2 (96.4-99.9)

Kappa value 0.96 0.96 0.96

Abbreviations: CI, confidence interval; HCV, hepatitis C virus; Neg, negative; NPV, negative predictive

value; OF, oral fluid; POC, point-of-care; Pos, positive; PPV, positive predictive value; WB, whole blood.

TABLE 3 Performance characteristics of DBS on the ARCHITECT
HCV antibody assay

Anti-HCV immunassay—DBS

Anti-HCV immunassay—PLASMA

Pos Neg Total

Pos 144 2 146

Neg 6 66 72

Total 150 68 218

Sensitivity (%, 95%CI) 96.0 (93.4-98.6)

Specificity (%, 95%CI) 97.06 (94.8-99.3)

PPV (%, 95%CI) 98.6 (97.1-100)

NPV (%, 95%CI) 91.7 (87.9-95.3)

Accuracy (%, 95%CI) 96.3 (93.8-98.8)

Kappa value 0.92

Abbreviations: DBS, dry blood spot; HCV, hepatitis C virus; Neg, negative;

NPV, negative predictive value; Pos, positive; PPV, positive predictive

value.

6 of 11 PRABDIAL-SING ET AL.



TABLE 4 Comparison of HCV RNA
viral load between plasma and DBS
samples on the CAP/CTM Viral load—DBS

Viral load—Plasma

≥15 IU/mL ≤15 IU/mL (LDL) Virus not detected (TND) Total

≥15 IU/mL 107 1 0 108

≤15 IU/mL (LDL) 2 0 0 2

Virus not detected 4 1 27 32

Total 113 2 27 142

Sensitivity (%, 95%CI) 94.7 (91-98.4)

Specificity (%, 95%CI) 100

PPV (%, 95%CI) 99.1 (97.5-100)

NPV (%, 95%CI) 84.4 (90.3-78.4)

Accuracy (%, 95%CI) 94.4 (98.2-90.5)

Kappa value 0.77

Abbreviations: DBS, dry blood spot; HCV, hepatitis C virus; LDL, lower than detectable limit; Neg,

negative; NPV, negative predictive value; PPV, positive predictive value; TND, target not detected.

F IGURE 2 Correlation of dried blood spots (DBS) to plasma viral load (log10IU/mL) on CAP/CTM, A, before application of the normalization
coefficient to the raw DBS results, B, after application of the normalization coefficient

F IGURE 3 Bland-Altman plot analysis of the differences between viral load in plasma and dried blood spots (DBS) (log10 IU/mL) on
CAP/CTM, A, without application of normalization coefficient, B, corrected DBS (log10 IU/mL) viral load

PRABDIAL-SING ET AL. 7 of 11



5 | DISCUSSION

With a high HCV seroprevalence and viraemic prevalence in PWID in

South Africa,10 it is of dire need that we simplify hepatitis C screening

and diagnostics. This study examined the use of POC tests and DBS

for anti-HCV screening and HCV RNA quantification in high risk

populations (PWID/UD, MSM and SWs). Although a few studies on

HCV Oraquick POC have been conducted in United States and

Korea,25 this is the first study to report on the Oraquick POC on

whole blood and oral fluid, as well as antibody and HCV RNA quantifi-

cation using DBS in high risk populations in SSA. In our country and

many others in SSA, there is poor or no access to laboratories in

remote regions. DBS can be transported from rural areas to central-

ized laboratories, as well as, provide a less painful way to get more

people tested.

Our results showed that the OraQuick HCV POC testing on

either whole blood or oral fluid yielded high sensitivities (97%-99%)

and specificities (97%-100%). Similar results of 100% specificity on

oral fluid were reported by Reference 41 in Europe, in patients who

were at-risk for hepatitis C. In Reference 42 study on whole blood

POC in the United States on people at-risk, a lower sensitivity of

92.7% was reported compared to ours of 99% and a higher specificity

of 99.8%, compared to ours of 97%. Interestingly, we had higher spec-

ificity on oral fluid POC than on whole blood POC. In total, we had

three false-positive results which could occur due to poor adherence

to decontamination procedures in between testing and handling of

devices or incorrect reading of visual results, or autoimmunity.43 Of

the eight false-negative results, five had viral load. Although, co-

infection with HIV may diminish HCV antibody responses and could

be a reason for false-negative results on rapid assays,24,42,44 we found

only one false-negative test POC result among HIV-coinfected partici-

pants. This is an important finding as SSA has the highest HIV preva-

lence in the world. We did not find any evidence that genotypes, low

viral load or serum HCV antibody titer can affect POC test results.

Our results do suggest that POC testing using HCV OraQuick, with

high levels of accuracy on both whole blood and oral fluid, make it a

good option for HCV screening among at-risk groups of people. Oral

fluid sampling is easier, particularly for PWID/UD's and is likely to be

more acceptable for higher risk populations and for use in community

health care settings.45

To decrease the occurrence of false results, education and train-

ing of field operators and healthcare workers at facilities that offer

POC testing becomes pivotal.46,47 It is imperative that correct times

for rapid diagnostic tests are adhered to, so to prevent false results. If

the time range is too wide (as with the 20-40 minutes for OraQuick

HCV test) for field workers to work with, this may account for varia-

tions in time keeping. Further studies are on the way to determine the

most effective time for a reliable POC result, bearing in mind that

quality assurance, calibration of timers and clocks at healthcare facili-

ties is required.48,49

DBS can increase the number of people screened, diagnosed and

ultimately treated especially among high risk groups.50,51 In areas,

such as SSA, where there is a high drop-off rate in the cascade of care,

a once-off sampling on DBS can provide further samples for HCV con-

firmatory testing.52 Again in SSA, where there is high endemicity of

HIV, HBV and TB, DBS is of particular advantage to surveillance stud-

ies as the spots can be used for HCV, HBV, HIV, and TB testing.

Many of the hepatitis C DBS studies have been conducted in

Europe, the United States and Brazil.32,33,53 Our DBS analyses on the

HCV ARCHITECT immunoassay showed sensitivity and specificity of

greater than 95% and a kappa value of 0.92, even when using the sig-

nal to reference cut-off ratios as recommended in the assay. With

DBS testing, however, the volume of blood in DBS collection is lim-

ited, increasing the possibility of false-negative and false-positive

reporting.54

On DBS for HCV quantitative testing, a sensitivity and accuracy

of 94% was found in our study. Comparatively, in similar studies using

the CAP/CTM, a larger cohort of 511 patients, in France, with known

HCV serostatus, showed a sensitivity of 97% and specificity of

100%55 and in a smaller study, in the United States on 48 HCV

chronic individuals, a sensitivity of 98% was reported.40 Much work

still remains to be done in terms of standardizing the methods when

using DBS and establishing better signal to cut-off ratios for serologi-

cal and threshold cut-off for molecular tests.

In our study, a strong correlation (R2 = 0.90) and good agreement

between viral load measurements for DBS and plasma samples was

observed. This demonstrates that the two testing sample matrices are

not markedly different from each other. Similar results with a strong

correlation of R2 = 0.97 in Reference 40 study and R2 = 0.90 in Refer-

ence 55 were shown. By applying the correction factor to our DBS

results, the correlation did not improve. Similar findings have also

been reported,40 due to the loss of HCV RNA in the DBS during

amplification and quantification.40

In the Bland-Altman plot agreement, after normalization, the bias

between plasma and DBS improved from 0.5 to 0.16 log10

IU/mL. Outliers were observed in the Bland-Altman analysis; these

outliers could be a result of the overcorrected DBS results since some

observations on the DBS had HCV viral loads higher than in plasma.

Overall, the results indicate that on average, CAP/CTM measures

0.16 log10 IU/mL more on plasma samples compared to DBS. Our

results show that for low viral loads on plasma, there was an under-

quantification on DBS. Bennet et al50 reported a low threshold of

250 IU/mL for HCV RNA testing on DBS. We found discordant

results on DBS for plasma viral load of ≤100 IU/mL. Usually in clinical

disease, HCV viral load is high as seen in our study (~105 IU/mL) and

for confirming HCV infection, low viral load is not clinically relevant.56

We noted that by using threshold values of CAP/CTM, we could not

use the normalization coefficient to the LDL results and hence, there

was no correction for LDL results on DBS. We suggest results with

LDL on DBS be interpreted with caution when using the CAP/CTM

assay. Further studies are necessary to monitor cut-offs on DBS using

the CAP/CTM for monitoring treatment outcomes.

The low HCV viral load observed in DBS (accounting to the low

kappa value of 0.77) can be due to the different input volumes in

whole blood (50 μL) and plasma (650 μL) when testing on the

CAP/CTM instrument. However, techniques to elute virus from DBS

8 of 11 PRABDIAL-SING ET AL.



for the CAP/CTM method may require further optimization. With

DBS, there may be a reduced sensitivity of viral RNA amplification, as

shown for HIV.57,58 A possibility of nucleic acid entrapment in the

DBS cards and suboptimal elution of the nucleic acid from the filter

paper could be another explanation for the difference in HCV RNA

levels observed in DBS.40 Increasing the number of DBS spots

(±50 μL) to test could be a feasible solution.40,59 For optimization

studies, the number of DBS cards collected per individual may be

increased from one to two so as to perform repeat testing. Increasing

DBS spots from two to three may alleviate the under-quantitation

seen on DBS at lower plasma viral loads. However, as with all capillary

blood spotting, spots should be completely covered to give correct

and reproducible results.60 We also recommend the use of the perfo-

rated spots, provided the spot is properly filled with blood. The perfo-

ration makes for easy removal and eliminates any carry-over from

cutting or punching of spots.

Our study was performed in a well-controlled setting with DBS

delivered in cold chain. It is recommended that DBS should be deliv-

ered without refrigeration within 2 days after collection to the cen-

tralized laboratory as storage conditions of DBS have been reported

to have an impact on the stability of nucleic acid.32,59 For diagnostic

DBS testing, as with the HIV early infant diagnosis61 in our country, it

is then imperative to have an integrated, efficient and reliable labora-

tory transport system.

Our study has provided a working methodology on how to per-

form HCV antibody and viral load testing on DBS using the ARCHI-

TECT HCV assay and CAP/CTM, respectively. For the latter, we have

also provided a working calculation on normalization coefficients

using the hematocrit value of 50% as an assumption. We have, never-

theless, shown how vital it is to correct for sample type and volume

difference by applying normalization coefficients to the DBS results.

We recommend that DBS be considered for use as a sample matrix

for molecular testing in high risk populations, bearing in mind, that the

procedure of using DBS on testing platforms may be considered off-

label, as it has not been validated by the manufacturer. More evalua-

tion studies are needed to provide supporting evidence for DBS use

on commercial assays, with proper standardized methods for correc-

tion factors, elution and testing.

There were limitations to our study. It was performed in a refer-

ence laboratory with controlled temperatures on instruments and lab-

oratories. We did not investigate the impact of environmental

conditions, such as temperature and humidity on DBS storage, trans-

port and testing. Our study cannot generalize to field settings where

transport and storage of DBS samples from clinics to centralized labo-

ratories may vary. More studies are needed to assess these factors in

areas with more constrained health systems or transporting of sam-

ples over greater distances. We assessed the performance of DBS

tests using venous whole blood. Future studies should look at spotting

capillary (finger-stick) blood in real-life clinical settings to note any dif-

ference in test performance.

In conclusion, we have demonstrated that POC testing on whole

blood or oral fluid is feasible and accurate. POC testing for HCV anti-

body should replace the current screening algorithms in South Africa

for at-risk populations. If oral fluid is more acceptable and comfortable

for POC testing, then this sample should be used, particularly where

vein access is difficult. In parts of SSA, where decentralization and

POC viral load tests are not options, then a positive anti-HCV POC

result should be followed by venous whole blood or DBS collection

and sent to a central laboratory to assess HCV viremia. This simplifies

the testing algorithm at the centralized laboratory to only one test.

We propose this testing algorithm in a country, such as South Africa,

with a mix of a well-established central laboratories in many parts of

the country and a reasonably efficient laboratory transport system to

transport DBS/blood samples from outlying rural areas to central test-

ing laboratories.

ACKNOWLEDGMENTS

The study was possible through addition to existing HIV prevention

and testing services supported by the United States President's Emer-

gency Plan for AIDS Relief and the United States Centers for Disease

Control and Prevention and the Global Fund. We acknowledge the

team at Centre for Vaccines and Immunology for collecting samples,

logistics and administration. We would also thank members at the

Centre for HIV and STIs for the timely use of the testing equipment.

We thank Jason Grebely from Kirby Institute, UNSW Sydney for his

suggestions to the article. Finally, we thank the Bristol-Meyers Squibb

Foundation for the financial support to perform the study.

FUNDING

Funding for the study was received from the Bristol-Myers Squibb

Foundation. The funder was not involved in the design of the study,

or the collection, analysis or interpretation of data.

CONFLICT OF INTEREST

Andrew Scheibe received an honourarium from Gilead for presenting

work in this field.

AUTHOR CONTRIBUTIONS

Conceptualization: Nishi Prabdial-Sing, Andrew Scheibe

Data curation: Morubula Jack Manamela, Andrew Scheibe, Katherine

Young

Formal analysis: Morubula Jack Manamela, Andrew Scheibe, Nishi

Prabdial-Sing, Lucinda Gaelejwe

Funding acquisition: Andrew Scheibe, Nishi Prabdial-Sing

Investigation: Nishi Prabdial-Sing, Lucinda Gaelejwe, Lillian

Makhathini, Jayendrie Thaver, Susan Malfeld

Methodology: Nishi Prabdial-Sing, Andrew Scheibe, Katherine Young

Project administration: Andrew Scheibe, Nishi Prabdial-Sing

Supervision: Nishi Prabdial-Sing, C. Wendy Spearman, Mark

Sonderup, Harry Hausler, Adrian J. Puren

Validation: Lucinda Gaelejwe, Nishi Prabdial-Sing, Andrew Scheibe,

Katherine Young

Visualization: Lucinda Gaelejwe, Nishi Prabdial-Sing, Andrew Scheibe,

C. Wendy Spearman, Mark Sonderup

Writing - original draft preparation: Lucinda Gaelejwe, Nishi

Prabdial-Sing

PRABDIAL-SING ET AL. 9 of 11



Writing - review and editing: Nishi Prabdial-Sing, Lucinda Gaelejwe,

Lillian Makhathini, Jayendrie Thaver, Morubula Jack Manamela, Susan

Malfeld, C. Wendy Spearman, Mark Sonderup, Andrew Scheibe,

Katherine Young, Harry Hausler, Adrian J. Puren

All authors have read and approved the final version of the

manuscript.

Nishi Prabdial-Sing had full access to all of the data in this study

and takes complete responsibility for the integrity of the data and the

accuracy of the data analysis.

TRANSPARENCY STATEMENT

The lead author affirms that this manuscript is an honest, accurate,

and transparent account of the study being reported; that no impor-

tant aspects of the study have been omitted; and that any discrepan-

cies from the study as planned (and, if relevant, registered) have been

explained.

DATA AVAILABILITY STATEMENT

The authors confirm that the data supporting the findings of this

study are available within the article.

ORCID

Nishi Prabdial-Sing https://orcid.org/0000-0002-5300-0245

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How to cite this article: Prabdial-Sing N, Gaelejwe L,

Makhathini L, et al. The performance of hepatitis C virus

(HCV) antibody point-of-care tests on oral fluid or whole

blood and dried blood spot testing for HCV serology and viral

load among individuals at higher risk for HCV in South Africa.

Health Sci Rep. 2021;4:e229. https://doi.org/10.1002/

hsr2.229

PRABDIAL-SING ET AL. 11 of 11

https://www.who.int/hepatitis/publications/annex_5-9-2.pdf?ua=1
https://www.who.int/hepatitis/publications/annex_5-9-2.pdf?ua=1
http://www.OpenEpi.com
https://www.cdc.gov/hiv/pdf/testing/cdc-hiv-factsheet-false-positive-test-results.pdf
https://www.cdc.gov/hiv/pdf/testing/cdc-hiv-factsheet-false-positive-test-results.pdf
https://doi.org/10.1002/hsr2.229
https://doi.org/10.1002/hsr2.229

	The performance of hepatitis C virus (HCV) antibody point-of-care tests on oral fluid or whole blood and dried blood spot t...
	1  INTRODUCTION
	2  METHODS AND MATERIALS
	2.1  Study setting
	2.2  Sample
	2.3  Blood collection, point-of-care testing and DBS preparation
	2.4  Blood and DBS transport and receipt

	3  LABORATORY TESTING
	3.1  Antibody testing
	3.2  Viral load testing
	3.3  Statistical analysis
	3.4  Ethics

	4  RESULTS
	4.1  POC results
	4.2  Anti-HCV POC compared to the reference laboratory immunoassay
	4.2.1  Whole blood POC
	4.2.2  Oral fluid POC

	4.3  Anti-HCV DBS compared to plasma on the reference laboratory immunoassay
	4.3.1  HCV viral load DBS compared to plasma on reference quantitative assay

	4.4  HCV viral load correlation between DBS and plasma
	4.4.1  HCV viral load agreement between DBS and plasma


	5  DISCUSSION
	ACKNOWLEDGMENTS
	  FUNDING
	  CONFLICT OF INTEREST
	  AUTHOR CONTRIBUTIONS
	  TRANSPARENCY STATEMENT
	  DATA AVAILABILITY STATEMENT

	REFERENCES