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Journal of Translational Medicine
Published in: Journal of Translational Medicine 1/2019

Open Access 01-12-2019 | Human Immunodeficiency Virus | Research

A methodology for deriving the sensitivity of pooled testing, based on viral load progression and pooling dilution

Authors: Ngoc T. Nguyen, Hrayer Aprahamian, Ebru K. Bish, Douglas R. Bish

Published in: Journal of Translational Medicine | Issue 1/2019

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Abstract

Background

Pooled testing, in which biological specimens from multiple subjects are combined into a testing pool and tested via a single test, is a common testing method for both surveillance and screening activities. The sensitivity of pooled testing for various pool sizes is an essential input for surveillance and screening optimization, including testing pool design. However, clinical data on test sensitivity values for different pool sizes are limited, and do not provide a functional relationship between test sensitivity and pool size. We develop a novel methodology to accurately compute the sensitivity of pooled testing, while accounting for viral load progression and pooling dilution. We demonstrate our methodology on the nucleic acid amplification testing (NAT) technology for the human immunodeficiency virus (HIV).

Methods

Our methodology integrates mathematical models of viral load progression and pooling dilution to derive test sensitivity values for various pool sizes. This methodology derives the conditional test sensitivity, conditioned on the number of infected specimens in a pool, and uses the law of total probability, along with higher dimensional integrals, to derive pooled test sensitivity values. We also develop a highly accurate and easy-to-compute approximation function for pooled test sensitivity of the HIV ULTRIO Plus NAT Assay. We calibrate model parameters using published efficacy data for the HIV ULTRIO Plus NAT Assay, and clinical data on viral RNA load progression in HIV-infected patients, and use this methodology to derive and validate the sensitivity of the HIV ULTRIO Plus Assay for various pool sizes.

Results

We demonstrate the value of this methodology through optimal testing pool design for HIV prevalence estimation in Sub-Saharan Africa. This case study indicates that the optimal testing pool design is highly efficient, and outperforms a benchmark pool design.

Conclusions

The proposed methodology accounts for both viral load progression and pooling dilution, and is computationally tractable. We calibrate this model for the HIV ULTRIO Plus NAT Assay, show that it provides highly accurate sensitivity estimates for various pool sizes, and, thus, yields efficient testing pool design for HIV prevalence estimation. Our model is generic, and can be calibrated for other infections.
Appendix
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Literature
1.
2.
Aprahamian H, Bish DR, Bish EK. Residual risk and waste in donated blood with pooled nucleic acid testing. Stat Med. 2016;35(28):5283–301.CrossRef
3.
Aprahamian H, Bish EK, Bish DR. Adaptive risk-based pooling in public health screening. IISE Trans. 2018;50(9):753–66.CrossRef
4.
Bish EK, Ragavan PK, Bish DR, Slonim AD, Stramer SL. A probabilistic method for the estimation of residual risk in donated blood. Biostatistics. 2014;15(4):620–35.CrossRef
5.
Biswas R, Tabor E, Hsia CC, Wright DJ, Laycock ME, Fiebig EW, Peddada L, Smith R, Schreiber GB, Epstein JS, Nemo GJ, Busch MP. Comparative sensitivity of HBV NATs and HBsAg assays for detection of acute HBV infection. Transfusion. 2003;43(6):788–98.CrossRef
6.
Busch MP. HIV, HBV and HCV: new developments related to transfusion safety. Vox Sang. 2000;78:253–6.CrossRef
7.
8.
9.
Dorfman R. The detection of defective members of large populations. Ann Math Stat. 1943;14(4):436–40.CrossRef
10.
Fiebig EW, Wright DJ, Rawal BD, Garrett PE, Schumacher RT, Peddada L, Heldebrant C, Smith R, Conrad A, Kleinman SH, Busch MP. Dynamics of HIV viremia and antibody seroconversion in plasma donors: implications for diagnosis and staging of primary HIV infection. AIDS. 2003;17(13):1871–9.CrossRef
11.
12.
Glynn SA, Wright DJ, Kleinman SH, Hirschkorn D, Tu Y, Heldebrant C, Smith R, Giachetti C, Gallarda J, Busch MP. Dynamics of viremia in early hepatitis C virus infection. Transfusion. 2005;45(6):994–1002.CrossRef
13.
Hughes-Oliver JM, Rosenberger WF. Efficient estimation of the prevalence of multiple rare traits. Biometrika. 2000;87(2):315–27.CrossRef
14.
Hughes-Oliver JM, Swallow WH. A two-stage adaptive group-testing procedure for estimating small proportions. J Am Stat Assoc. 1994;89(427):982–93.CrossRef
15.
Karris MY, Anderson CM, Morris SR, Smith DM, Little SJ. Cost savings associated with testing of antibodies, antigens, and nucleic acids for diagnosis of acute HIV infection. J Clin Microbiol. 2012;50(6):1874–8.CrossRef
16.
Litvak E, Tu XM, Pagano M. Screening for the presence of a disease by pooling sera samples. J Am Stat Assoc. 1994;89(426):424–34.CrossRef
17.
Liu A, Liu C, Zhang Z, Albert PS. Optimality of group testing in the presence of misclassification. Biometrika. 2012;99(1):245–51.CrossRef
18.
Nguyen NT, Bish EK, Aprahamian H. Sequential prevalence estimation with pooling and continuous test outcomes. Stat Med. 2018;37(15):2391–426.CrossRef
19.
Nguyen NT, Bish EK, Bish DR. Optimal pooled testing design for prevalence estimation. Working paper. Department of Industrial and Systems Engineering, Virginia Tech; 2018.
20.
Pilcher CD, Joaki G, Hoffman IF, Martinson FEA, Mapanje C, Stewart PW, Powers KA, Galvin S, Chilongozi D, Gama S, Price MA, Fiscus AF, Cohen MS. Amplified transmission of HIV-1: comparison of HIV-1 concentrations in semen and blood during acute and chronic infection. AIDS. 2007;21(13):1723.CrossRef
21.
Shyamala V. Nucleic acid technology (NAT) testing for blood screening: impact of individual donation and mini pool-NAT testing on analytical sensitivity, screening sensitivity and clinical sensitivity. ISBT Sci Ser. 2014;9(2):315–24.CrossRef
22.
Stramer SL, Krysztof DE, Brodsky JP, Fickett TA, Reynolds B, Dodd RY, Kleinman SH. Comparative analysis of triplex nucleic acid test assays in United States blood donors. Transfusion. 2013;53(10):2525–37.CrossRef
23.
Thompson KH. Estimation of the proportion of vectors in a natural population of insects. Biometrics. 1962;18(4):568–78.CrossRef
24.
Tu XM, Litvak E, Pagano M. On the informativeness and accuracy of pooled testing in estimating prevalence of a rare disease: application to HIV screening. Biometrika. 1995;82(2):287–97.CrossRef
25.
Vansteelandt S, Goetghebeur E, Verstraeten T. Regression models for disease prevalence with diagnostic tests on pools of serum samples. Biometrics. 2000;56(4):1126–33.CrossRef
26.
Wein LM, Zenios SA. Pooled testing for HIV screening: capturing the dilution effect. Oper Res. 1996;44(4):543–69.CrossRef
27.
Weusten J, Van Drimmelen H, Lelie N. Mathematic modeling of the risk of HBV, HCV, and HIV transmission by window-phase donations not detected by NAT. Transfusion. 2002;42(5):537–48.CrossRef
28.
Weusten J, Vermeulen M, van Drimmelen H, Lelie N. Refinement of a viral transmission risk model for blood donations in seroconversion window phase screened by nucleic acid testing in different pool sizes and repeat test algorithms. Transfusion. 2011;51(1):203–15.CrossRef
29.
30.
Zenios SA, Wein LM. Pooled testing for HIV prevalence estimation: exploiting the dilution effect. Stat Med. 1998;17(13):1447–67.CrossRef
31.
Zhang Z, Liu C, Kim S, Liu A. Prevalence estimation subject to misclassification: the mis-substitution bias and some remedies. Stat Med. 2014;33(25):4482–500.CrossRef
Metadata
Title
A methodology for deriving the sensitivity of pooled testing, based on viral load progression and pooling dilution
Authors
Ngoc T. Nguyen
Hrayer Aprahamian
Ebru K. Bish
Douglas R. Bish
Publication date
01-12-2019
Publisher
BioMed Central
Published in
Journal of Translational Medicine / Issue 1/2019
Electronic ISSN: 1479-5876
DOI
https://doi.org/10.1186/s12967-019-1992-2

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