A microarray-based pathogen chip for simultaneous molecular detection of transfusion–transmitted infectious agents

Each year over 112 million blood donations are collected globally and nearly 21 million blood components are transfused in the U.S. [1]. Though screening of these blood units using serologic and nucleic acid testing (NAT) has greatly reduced the risk of some transfusion–transmitted infections, the vast majority of bloodborne agents are not screened [2‐4]. The U.S. Food and Drug Administration (FDA) licensed methods for infectious disease screening of donor blood include (1) NAT for Hepatitis B virus (HBV), Hepatitis C virus (HCV), HIV 1 and 2, Babesia, West Nile virus (WNV) and Zika virus (ZIKV); and (2) immunoassays for HBV, HCV, HIV-1, 2, cytomegalovirus (CMV), human T cell lymphotropic virus I and II (HTLV), Treponema pallidum (syphilis) and Trypanosoma cruzi (Chagas). HTLV, syphilis and Chagas antibody testing fail to detect these pathogens during early infection and Chagas is screened only once on samples from first-time blood donors [5].

The American Association of Blood Banks (AABB) Transfusion–Transmitted Diseases Committee produced a list of over 30 pathogens of concern for transmission via blood that included bacteria, parasites, prions and viruses [6]. Only prions cannot be detected by currently available technology. Nearly all the other agents require individual qPCR or serologic testing and it is logistically impractical and cost prohibitive to test all known and potential agents individually [7‐9].

Multiplex PCR-based devices for testing blood-borne pathogens are limited. Two FDA-approved blood donor screening assays (Cobas Taqscreen MPX Test, Roche Molecular Systems, Inc. and the Procleix Ultrio Plus,Gen-Probe, Inc.) use PCR or transcription-mediated amplification methodology for multiplex detection of HBV, HCV, and HIV 1–2 [5]. A multiplex assay capable of detecting all known pathogens of concern in a single small blood sample with high sensitivity and specificity could significantly increase the safety of the blood supply. Further, to counter emerging pathogens, the platform should be adaptable for rapid addition and validation of probes to detect new agents. Microarray-based technology offers the advantage of multiplex detection in a miniaturized format with high adaptability. The presence of multiple probes per target represent an advantage in comparison to traditional NAT or EIA assays since the pathogen can be detected even if mutations block the effectiveness of some probes [10]. The flexibility and high-throughput capability of microarrays hold great potential for pathogen detection and identification, but historically have limitations in detecting agents present at low copy numbers. [11‐13]. To optimize performance and improve detection limits, we implemented two strategies: (1) a platform design that simultaneously detects and distinguishes multiple pathogens and closely related viral strains; and (2) an innovative combination of amplification and labeling protocols to detect multiple targets present at low levels in a single sample.

In this proof of concept study, we evaluated the performance of a customized microarray-based pathogen chip for simultaneous detection of 16 RNA viruses in human plasma samples that is designed to have the flexibility to expand to detect emerging agents in a relatively short time frame. A parallel, and ultimately integrated, chip to detect DNA viruses, bacteria and parasites is in development. Platform performance was evaluated using positive plasma donor samples and pathogen-spiked plasma.

The pathogen chip design strategy was to cover all high priority bloodborne RNA viruses (retroviruses, and both positive- and negative-strand RNA viruses) using multiple probes to independent target sites in the genome of each species. In total, 1769 unique viral oligonucleotides derived from 16 distinct viral genomes were selected that allowed discrimination of pathogens at the level of species, subtypes and genotypes (Table 1). The final microarray design was supplemented with negative controls, including predesigned GE array probes for 906 genes from the human genome, 84 ERCC probes and 120 probes specific for plant viruses (Table 1). The eArray quality scoring evaluation (BC quality scores: BC1, high; BC3, low) revealed that nearly 90% of the selected probes had a high quality score (87% BC1, 13% BC2, 0.1% BC3).

The design included multiple gene targets for each pathogen genome in order to select the best probes for the final platform design. Probes selected in the final design generated a more intense signal and produced higher percentage coverage of the specific genome across the different experiments (Additional file 2: Figure S1a, b).

Blood donors in the U.S. are routinely screened for ten infectious agents; six using nucleic acid detection methodology and four with immunoassays. However, more than thirty pathogens pose a significant threat to the blood supply [3, 6]. Multiplex screening exists only for detection of HBV, HCV and HIV. Recent emergent threats, such as WNV and ZIKV, have been added to the growing list of individual tests required for blood donor screening.

Microarrays are miniaturized detection platforms consisting of short (25-mer to 70-mer) single-stranded oligonucleotide probes deposited onto a solid substrate. A microarray-based platform has the advantage of having a small solid surface upon which thousands of oligonucleotide probes can be printed to simultaneously detect a multiplicity of target pathogens [16‐18]. Fluorescently labeled nucleic acid samples are hybridized to the microarray, and hybridization patterns are analyzed to identify the specific pathogens that are present. A dedicated multi-pathogen detection platform for blood donor screening with a short processing time and well-defined processes for data analysis could significantly improve the safety of the blood supply.

We described here early-stage design, development and validation of a microarray-based pathogen chip to screen blood donors for transfusion–transmitted RNA viruses. We developed an array design, sample material preparation method, hybridization conditions and a single (non-primer specific) amplification step for detection of 16 viral pathogens without compromising performance. We determined the limit of detection of these viruses in human plasma specimens tested individually, or as a mixture of up to eight different pathogens. We also developed a method for data analysis and interpretation capable of discriminating multiple viruses in the same sample set.

The design included multiple gene targets for each pathogen genome in order to increase the sensitivity of the platform. The intensities of individual probes in a probe set can vary substantially and the contributions of peak intensities within the set can be obscured through averaging, so if the virus species are under-represented by the array probe sets, the detection of that specific target can be missed. In order to increase the platform coverage of the virus landscape to which the array is designed to target, the design strategy was to balance the number of probes for each pathogen to a final count of 90–110 probes previously determined to be the most reactive. Another fundamental step to increase the level of sensitivity was to increase the quantity of RNA targets for hybridization through sample amplification. We designed a novel workflow combining two different applications, in use independently, but never combined, to increase the concentration of target nucleic acids. We applied a sequence independent, single primer linear isothermal amplification (Ribo-SPIA) procedure for preparation of target cDNA [19]. This approach allowed detection of low viral RNA copy numbers without the necessity of designing specific primers for each pathogen. Nearly all known PCR-positive samples were detected on the platform and all the probes generated a strong signal specific for each positive plasma specimen analyzed. There were no specific signals produced by negative control plasma, and only in a few arrays were random nonspecific intensity signals produced. This indicated that the generation of cDNA instead of amplified RNA, followed by Cy3 labeling and hybridization based on a DNA application, worked almost perfectly. Among the 99 positive samples tested at a concentration ranging from 10⁵ to 10² copies/mL, 95 (96%) were correctly detected at all concentrations. Only HEV failed to be detected in 4 of 7 PCR-positive samples with a 10⁴ copies/mL limit of detection.

Blood donors may uncommonly be co-infected with more than one agent, and therefore multiple pathogens need to be distinguished simultaneously. The mixes of between 3 and 8 different pathogens at different concentrations were identified, with no interference among the targets, at a 10³ limit of detection.

The potential of some viruses to mutate with high frequency, and the need to rapidly develop a new test for emerging pathogens in response to outbreaks, are important factors to consider during multi-pathogen detection platform design. An ideal multiplex device should have the flexibility to expand to detect emerging agents and, at the same time, have a relatively short validation time frame. We were able to modify the probe design, and manufacture an updated version of the pathogen chip in less than 4 weeks during the 2016 ZIKV outbreak. The expansion with ZIKV-specific probes did not alter platform performance.

The aims of the study were to optimize platform performance, improve the limits of detection and develop a method for data analysis and interpretation. The use of spiked specimens was useful to evaluate the reproducibility and practicality of the new platform. The spiked specimens represented a standardized method to facilitate the evaluation of probe design, amplification strategies, and bioinformatics analysis among different experiments. The next phase of development will include attainment specimens from patients who had been infected with one or more agents and evaluation of platform performance against a blinded panel of known positive and negative clinical samples.

Overall, this microarray-based pathogen-chip met the predicted discriminating ability for multi-pathogen detection. Using optimized methods for sample preparation, labelling, and hybridization, this platform achieved simultaneous molecular detection of sixteen transfusion–transmitted RNA viruses. In this format, oligonucleotide probes, rigorously validated for specificity, sensitivity, and reproducibility, showed strong correlation with independent RT-qPCR quantitation, down to a level of 10² copies/mL. These attributes, combined with successful simultaneous discrimination between up to eight pathogens and the potential for rapid addition of new detection targets, make this design a promising step towards improvements in donor blood safety. An integrated pathogen chip to detect RNA and DNA viruses, bacteria and parasites is in development.

In this proof of concept study, we evaluated the performance of a customized microarray-based pathogen chip for simultaneous detection of 16 RNA viruses in human plasma samples that is designed to have the flexibility to expand to detect emerging agents in a relatively short time frame. Following proof of concept validation, the platform could be commercially developed for blood donor screening and diagnostic use with potential for other blood pathogen screening applications. The ability to rapidly test both large numbers of donors or a single donor sample (with a consistent cost per sample) for all pathogens of concern with a single multiplex test, keeping the same sensitivity and specificity of single tests would significantly enhance the safety of the blood supply.