An alternative strategy to western blot as a confirmatory diagnostic test for HIV infection

An alternative strategy to western blot as a confirmatory diagnostic test for HIV infection

Accepted Manuscript Title: An Alternative Strategy to Western Blot as a Confirmatory Diagnostic Test for HIV Infection Author: Xia Feng Jibao Wang Zhi...

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Accepted Manuscript Title: An Alternative Strategy to Western Blot as a Confirmatory Diagnostic Test for HIV Infection Author: Xia Feng Jibao Wang Zhiyun Gao Yu Tian Ling Zhang Huichao Chen Tong Zhang Lin Xiao Jun Yao Wenge Xing Maofeng Qiu Yan Jiang PII: DOI: Reference:

S1386-6532(16)30638-2 http://dx.doi.org/doi:10.1016/j.jcv.2016.12.010 JCV 3750

To appear in:

Journal of Clinical Virology

Received date: Revised date: Accepted date:

25-8-2016 13-12-2016 20-12-2016

Please cite this article as: Feng Xia, Wang Jibao, Gao Zhiyun, Tian Yu, Zhang Ling, Chen Huichao, Zhang Tong, Xiao Lin, Yao Jun, Xing Wenge, Qiu Maofeng, Jiang Yan.An Alternative Strategy to Western Blot as a Confirmatory Diagnostic Test for HIV Infection.Journal of Clinical Virology http://dx.doi.org/10.1016/j.jcv.2016.12.010 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

An Alternative Strategy to Western Blot as a Confirmatory Diagnostic Test for HIV Infection An Alternative Strategy to Western Blot as a Confirmatory Diagnostic Test for HIV Infection

Xia Fenga,b, Jibao Wangc, Zhiyun Gaod, Yu Tiana, Ling Zhanga, Huichao Chene, Tong Zhangb, Lin Xiaof, Jun Yaoa, Wenge Xinga, Maofeng Qiua, Yan Jianga*

a

National HIV/HCV Reference Laboratory, National Center for AIDS/STD Control

and Prevention, China CDC, Beijing, China b

Department of Clinical Laboratory, Beijing Youan Hospital, Capital Medical

University, Beijing, China c

Center for Disease Control and Prevention in Dehong, Dehong, China

d

Department of Pathogenic Biology, Hebei Medical University, Shijiazhuang, China

e

Center for Disease Control and Prevention in Yunnan Province, Kunming, China

f

Center for Disease Control and Prevention in Liangshan, Liangshan, China

*Corresponding author:

Yan Jiang, National HIV/HCV Reference Laboratory, National Center for AIDS/STD Control and Prevention, China CDC, Beijing, China Telephone number: +86-13911096250; Fax number: 010-58900994 Email: [email protected] 1

Highlights 

The DBS–urine paired ELISA is equivalent to WB in HIV antibody detection.



The DBS–urine paired ELISA would be valuable in resource-limited regions.



The DBS–urine paired ELISA is affordable and easy to use.

Abstract Background In China, western blot (WB) is the recommended procedure for the diagnosis of HIV infection. However, this technique is time consuming and labor intensive, and its complexity restricts wide application in resource-limited regions. Objective The aim of this study was to evaluate the efficacy of a dry blood spots (DBS)–urine paired enzyme-linked immunosorbent assay (ELISA) test, instead of WB, for HIV antibody detection. Study design Plasma, DBS, and urine samples were collected from 1213 subjects from different populations. Two diagnostic testing strategies were conducted in parallel. The equivalence of the paired ELISA and WB strategies was assessed. Results A diagnosis of HIV was determined in 250 subjects according to the paired ELISA 2

test, and in 249 according to the WB strategy. The discordant case was judged HIV-positive during follow-up. In total, 18 subjects were diagnosed with possible HIV using the paired ELISA test, among whom, 11 subjects tested negative with WB, and one was confirmed to be HIV-positive during follow-up. For the remaining 945 subjects, both strategies indicated a negative result. The kappa test indicated good conformity (kappa = 0.954) between the two diagnostic strategies. Conclusion The DBS–urine paired ELISA could be applied as an alternative to WB in HIV diagnosis, which would be valuable in resource-limited regions owing to the associated affordability and ease of use.

Key words: ELISA; HIV; substitutive strategy; western blot 1. Background The Joint United Nations Programme on HIV/AIDS (UNAIDS) 90-90-90 program has become the common global target to help eradicate acquired immune deficiency syndrome (AIDS). The first 90 is the most important; by 2020, 90% of all people living with HIV will know their HIV status [1]. As far as HIV detection is concerned, it can meet the needs of detection when the window period is 14 days with the fourth-generation ELISA and 10 days with the nucleic acid test (NAT) [2]. However, in 2014, it was estimated that only 45% of all people with HIV were aware of their sero-status [3]. This low level may be related to the disparate capacities of laboratories, resulting from varying regional economies, and among key populations, 3

it may be associated with the fear of disclosing personal information and discrimination. Therefore, human immunodeficiency virus (HIV) diagnostic strategies have to be improved in both depth and breadth to satisfy the unmet needs. In China, the recommended test for confirmatory diagnosis of HIV infection is western blot (WB), which is widely used in the HIV testing network. For decades, this method has played an important role in the prevention and control of HIV. However, along with the development of new diagnostic methods, the popularity of WB faces several challenges such as a high rate of uncertainty, low sensitivity, and a long testing period, which could result in false-negatives for patients within the window period [4-8], and may also impede patients’ follow-up[8,9]. Moreover, in addition to regional differences in ethnicity, economy, and population, there is an uneven distribution of not only the prevalence of HIV infection but also the competency of HIV testing laboratories. Therefore, a single strategy is inadequate for HIV diagnosis. New diagnostic strategies with improved sensitivity, convenience, and regional applicability are needed for HIV/AIDS prevention and control. 2. Objectives In this study, the dry blood spot (DBS) and urine ELISA tests were combined as an alternative to WB. The practicability of the paired ELISA test was evaluated by direct comparison of these two strategies. 3. Study Design 3.1 Ethical considerations This study design was approved by the institution review board, and the 4

requirement for informed consent was waived. 3.2 Subjects From March 21, 2014 to January 31, 2015, a total of 1213 subjects were enrolled. This population included 261 subjects who were randomly selected from a population receiving a health examination by the disease prevention and control center (CDC), Liangshan Yi Autonomous Prefecture, Sichuan Province; 101 subjects with an HIV infection diagnosis confirmed by WB, with unknown transmission routes, sampled by Xichang sexually transmitted disease (STD) and skin disease prevention station; 251 drug users sampled by Dehong Prefecture CDC, Yunnan Province; and 600 men who have sex with men (MSM) sampled by Yunnan CDC and the outpatient service, Center for Infective Disease, Beijing Youan Hospital, Capital Medical University. 2.3 Sample processing Blood and urine samples were collected from each subject and numbered. Venous blood samples (3–5 mL) were centrifuged (3000 rpm/min), and serum was stored at 4°C. Urine samples (20–50 mL) were collected in special tubes that contain polymers to protect the antibody against degradation during transportation, and were stored at 4°C. 3.4 Reagents The urine HIV-1 antibody ELISA kits were provided by Beijing JunHe Pharmaceuticals Co., Ltd (Beijing, China). The blood HIV antibody ELISA kits were provided by Beijing Wantai Biological Pharmacy (Beijing, China). The WB kits for HIV antibody were provided by MP Biomedicals Asia Pacific Pte., Ltd (Singapore). 5

The NATs were performed for nucleic acid detection using the COBAS Ampli Prep/COBAS Taq Man HIV-1 Test (version 2.0) (Swiss). Internal quality control for the urine ELISA was formulated by mixing HIV-antibody positive plasma and HIV-antibody negative urine with signal to cutoff (S/CO) ratios of 3–5. Internal quality control for the blood ELISA was provided by Beijing Kinghawk Pharmaceutical Co., Ltd. (Beijing, China). 3.5 Testing procedure After sampling, all tests were performed within seven days by the same technician from the National Reference Laboratory, National Center for AIDS/STD Control and Prevention, China CDC. Samples from Dehong Prefecture were tested on site, but all of the other samples were transported to the National Reference Laboratory for testing. Blood samples were successively screened, retested, and confirmed in accordance with the National Guidelines for HIV Diagnosis (revised in 2009). Sero-positive and WB-negative samples were tested for HIV nucleic acid. For sero-negative samples, 50-sample pooled NATs were performed[10]. 3.6 DBS–urine paired ELISA test Urine and DBS samples were experiment as an alternative strategy,also screened by ELISA. An HIV positive diagnosis was indicated by positive results from both the DBS and urine samples in the parallel ELISA tests An HIV negative diagnosis was indicated by double negative results. In cases where either the DBS or urine ELISA indicated a positive result, “possible” HIV was diagnosed and further follow-up was required(Figure 1).. 6

3.7 Statistical analysis Concordance between blood ELISA, urine ELISA, WB, and NAT results was calculated,and the conformity between the paired ELISA and WB tests was evaluated using Kappa value. Data analyses were performed by using SPSS 19.0 (SPSS Inc., Chicago, IL) and p<0.05 was considered statistically significant. 4. Results For all 1213 subjects, the paired ELISA results were consistent with those of the WB blood analysis.Figure 2 presents a comparison of the WB and paired ELISA tests. In total, 250 subjects were confirmed to be HIV positive by the DBS–urine paired ELISA. Of these, 249 subjects were also positive on the WB. One subject had possible HIV with a band present at gp160 and a plasma viral load of 3.5 x 10 6 copies/mL. After one-month follow-up, the result for this case was positive with bands observed at p24, gp120, and gp160. These test results combined with clinical manifestations and epidemiological history indicated a diagnosis of early HIV infection. Overall, a positive result from the paired ELISA test was a good indicator of HIV infection. For the remaining 945 subjects both strategies indicated a negative result, confirmed by negative pooled NATs. There were 18 (1.48%) cases of “possible” HIV identified by the DBS–urine paired ELISA. Of the nine cases where DBS was positive and urine was negative, six screened positive with WB. The other three cases were negative by WB. Corresponding viral load tests indicated that, of the three cases, two were negative 7

and one had a viral load of 25 x 106 copies/mL. After 49 days follow-up, a repeated WB test showed a positive result with bands present at p24, gp41, gp120, and gp160 for this subject. Indicating that, for a sample taken within the window period, a false-negative is more likely with WB than the alternative testing strategy. In contrast, for the nine cases where urine was positive and DBS was negative, the WB results were all negative. The S/CO ratios for the urine ELISA were all low (1.052–2.032). These results suggest a potential for false-positive results with the urine antibody detection test. However, the World Health Organization (WHO) report that a positive urine HIV antibody test may indicate an HIV infection before blood HIV antibodies can be detected [11]. The cross-sectional design and lack of follow-up in our study mean that we cannot assess whether the positive urine tests are an early indication of infection in these cases. Therefore, further research is needed to investigate the value of urine antibody tests as early indicators of HIV infection. The sensitivity and specificity of the paired ELISA strategy were 97.6% (249/255) and 98.7%(945/957) when taking WB as the gold standard, respectively. The total concordance between the two diagnostic testing strategies was 98.43% (1194/1213), with good consistency (Kappa = 0.954 > 0.85, P = 0.000) (Figure 2). Direct comparison of the paired ELISA with WB shows that there is very good consistency between the two strategies.

5. Discussion The UNAIDS guidelines for using testing technologies in HIV surveillance state 8

that ELISA and rapid diagnostic tests (RDTs) are the most precise and cost-effective methods [15],and the use of ELISA and RDTs for HIV detection has been widely adopted internationally, including in the United States and in most European countries [16-20]. At present, only a few countries, such as China and France, use WB for the detection of HIV. Furthermore, WB faces several challenges such as a high rate of uncertainty, low sensitivity, and a long testing period which leads to the loss of patients. On the other hand, China’s use of WB for HIV diagnosis confirmation is contrary to the recommendations in the WHO’s 2015 consolidated guidelines on HIV testing services [15]. Therefore, China needs to reevaluate their testing strategies. A parallel screening technique using two blood ELISA tests from different manufacturers has been used in the blood donor screening program in China for more than 30 years, which has proven that practical application of a parallel ELISA method is feasible [21]. Since it was first approved by the US Food and Drug Administration in 1996, DBS has proved to be an efficient way of collecting samples and has equivalent accuracy to blood. DBS is now used in many countries in HIV surveillance [22-25]. In China, XiHui Zang [26] demonstrated equivalence between DBS and blood sampling methods. The same conclusion can be drawn from our study. Our research group has also demonstrated that excellent results can be gained through using urine samples for HIV antibody detection [27]. The sensitivity and specificity of urine HIV antibody testing are reported to be 69.7%~97% and 99%~100%, respectively [28,29], which are in line with our results. 9

When the paired ELISA with WB testing strategies wre compsred (table 2), for WB, the experimental process is time consuming, technical requirements are high, and interpretation of the results is difficult. Therefore, for remote and underdeveloped areas, samples need to be collected and submitted to a specialist HIV laboratory, which not only increases the burden on the HIV laboratory but also increases the turnaround time for the test results potentially leading to losses. This is the first study to evaluate an alternative method for HIV antibody detection using two biological samples and a parallel ELISA. This technique can not only identify cases of HIV infection, but also can get confirmatory results in a shorter time using ELISA. Furthermore, it is suitable for mass sampling. Moreover, this parallel strategy flags up possible infections that require follow-up and/or further diagnostic tests, which may reduce missed diagnosis of cases tested within the window period.

6. Conclusions In conclusion, the DBS–urine paired ELISA test can be applied as an alternative strategy for HIV diagnosis in remote and resource-limited areas. It may also be valuable for home-based self-testing in high-risk populations who do not want to be tested because of fears of discrimination. All above, this alternative strategy can increase the accessibility of HIV testing. The sample size in this study was limited, which may bias the results. Therefore, future research needs to be designed to evaluate the feasibility of the paired ELISA 10

strategy in different regions and in populations with different AIDS incidence rates.

Funding sources The work was supported by the National Science and Technology Major Project of the 12th Five-Year Plan (2013ZX10001001-001-007) and the Beijing Municipal Science and technology project (D141100000314003). The authors have no conflicts of interest to declare. Acknowledgements The authors would like to acknowledge all of the staff from the participating laboratories. We would also like to thank Mengjie Bai for providing helpful feedback on an earlier version of the paper.

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Figure 1. Parallel DBS and urine samples in the paired ELISA

Abbreviations: D= dry blood spots; U=urine

Figure 2. Sample processing and qualitative results

Abbreviations: DBS = dry blood spots; WB = western blot *One subject had possible HIV with a band present at gp160 and a plasma viral load of 3.5 x 106 copies/mL. After one-month follow-up, the result for this case was positive with bands observed at p24, gp120, and gp160.

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Table 1. Comparison of the results of the WB and paired ELISA strategies WB Total

Paired ELISA

+

Possible

-

+

249

1

0

250

Possible

6

0

12

18

-

0

0

945

945

255

1

957

1213

Total

Abbreviations: WB = western blot; ELISA = enzyme-linked immunosorbent assay. The total concordance between the two diagnostic testing strategies was 98.43% (1194/1213), Kappa = 0.954 , P = 0.000

Table 2. Comparison of the paired ELISA and WB testing strategies WB

Paired ELISA

Laboratory requirement

Confirmatory lab

Screening and confirmatory lab

Strategy design

Serial

Parallel

Operational convenience

Complicated

Easy

Testing period (days)

3~7[12,13]

1~2

Expense (RMB)

207.8~408.7 [14]

50~100

Ratio of uncertainty (%)

3.03~14.5 [5-8]

1.48

Possibility of false-negatives

High

Low

Abbreviations: WB = western blot; ELISA = enzyme-linked immunosorbent assay.

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