The Standardization and Control of Serology and Nucleic Acid Testing for Infectious Diseases

Overview

Journal Clin Microbiol Rev

Publisher American Society for Microbiology

Specialty Microbiology

Date 2021 Jul 28

PMID 34319148

Citations 6

Authors

Wayne Dimech

Affiliations

Soon will be listed here.

Abstract

Historically, the detection of antibodies against infectious disease agents was achieved using test systems that utilized biological functions such as neutralization, complement fixation, hemagglutination, or visualization of binding of antibodies to specific antigens, by testing doubling dilutions of the patient sample to determine an endpoint. These test systems have since been replaced by automated platforms, many of which have been integrated into general medical pathology. Methods employed to standardize and control clinical chemistry testing have been applied to these serology tests. However, there is evidence that these methods are not suitable for infectious disease serology. An overriding reason is that, unlike testing for an inert chemical, testing for specific antibodies to infectious disease agents is highly variable; the measurand for each test system varies in choice of antigen, antibody classes/subclasses, modes of detection, and assay kinetics, and individuals' immune responses vary with time after exposure, individual immune-competency, nutrition, treatment, and exposure to variable circulating sero- or genotypes or organism mutations. Therefore, unlike that of inert chemicals, the quantification of antibodies cannot be standardized using traditional methods. However, there is evidence that the quantification of nucleic acid testing, reporting results in international units, has been successful across many viral load tests. Similarly, traditional methods used to control clinical chemistry testing, such as Westgard rules, are not appropriate for serology testing for infectious diseases, mainly due to variability due to frequent reagent lot changes. This review investigates the reasons why standardization and control of infectious diseases should be further investigated and more appropriate guidelines should be implemented.

Citing Articles

Nanobiosensors Enable High-Efficiency Detection of Tuberculosis Nucleic Acid.

Li M, Shen C, Lv M, Luo Y JACS Au. 2025; 5(2):536-549.

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Laboratory development of an RNA quantitative RT-PCR assay reporting in international units for hepatitis D virus.

Osiowy C, Day J, Lee E Front Microbiol. 2024; 15:1472826.

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A modified quality control protocol for infectious disease serology based on the Westgard rules.

Wang Y, Li X, Li D, Xie Y Sci Rep. 2024; 14(1):16683.

PMID: 39030224 PMC: 11271505. DOI: 10.1038/s41598-024-67472-1.

The etiological diagnostic value of metagenomic next-generation sequencing in suspected community-acquired pneumonia.

Liu M, Zhang H, Li L, Mao J, Li R, Yin J BMC Infect Dis. 2024; 24(1):626.

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Monoclonal Antibodies as SARS-CoV-2 Serology Standards: Experimental Validation and Broader Implications for Correlates of Protection.

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