Optimisation and Standardisation of a Multiplex Immunoassay of Diverse Antigens to Assess Changes in Malaria Transmission Using Sero-epidemiology

Overview

Journal Wellcome Open Res

Specialty Biomedical Engineering

Date 2020 Jun 13

PMID 32518839

Citations 47

Authors

Lindsey Wu

Tom Hall

Isaac Ssewanyana

Tate Oulton

Catriona Patterson

Hristina Vasileva

Susheel Singh

Muna Affara

Julia Mwesigwa

Simon Correa

Mamadou Bah

Umberto DAlessandro

Nuno Sepulveda

Chris Drakeley

Kevin K A Tetteh

Affiliations

Soon will be listed here.

Abstract

Antibody responses have been used to characterise transmission and exposure history in malaria-endemic settings for over a decade. Such studies have typically been conducted on well-standardised enzyme-linked immunosorbent assays (ELISAs). However, recently developed quantitative suspension array technologies (qSAT) are now capable of high-throughput and multiplexed screening of up to hundreds of analytes at a time. This study presents a customised protocol for the Luminex MAGPIX qSAT using a diverse set of malaria antigens. The aim is to develop a standardised assay for routine serological surveillance that is implementable across laboratories and epidemiological settings. A panel of eight recombinant antigens, associated with long- and short-lived antibody responses, was designed for the Luminex MAGPIX platform. The assay was optimised for key steps in the protocol: antigen-bead coupling concentration, buffer composition, serum sample dilution, and bead storage conditions. Quality control procedures and data normalisation methods were developed to address high-throughput assay processing. Antigen-specific limits of quantification (LOQs) were also estimated using both in-house and WHO reference serum as positive controls. Antigen-specific bead coupling was optimised across five serum dilutions and two positive controls, resulting in concentrations operational within stable analytical ranges. Coupled beads were stable after storage at room temperature (22⁰C) for up to eight weeks. High sensitivity and specificity for distinguishing positive and negative controls at serum sample dilutions of 1:500 (AUC 0.94 95%CI 0.91-0.96) and 1:1000 (AUC 0.96 95%CI 0.94-0.98) were observed. LOQs were also successfully estimated for all analytes but varied by antigen and positive control. This study demonstrates that developing a standardised malaria-specific qSAT protocol for a diverse set of antigens is achievable, though further optimisations may be required. Quality control and data standardisation methods may also be useful for future analysis of large sero-epidemiological surveys.

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