# Biosensor Technologies for Avian Influenza Detection: A New Frontier in Rapid Diagnostics for HPAI

**Authors:** Jacquline Risalvato, Alaa H. Sewid, Durina Z. Dalrymple, Shigetoshi Eda, J. Jayne Wu, Richard W. Gerhold

PMC · DOI: 10.3390/bios16020118 · Biosensors · 2026-02-12

## TL;DR

This paper reviews biosensor technologies for detecting avian influenza, highlighting their potential to improve rapid diagnostics and support vaccination strategies.

## Contribution

The paper evaluates biosensor platforms as a novel solution for overcoming limitations in current avian influenza diagnostics.

## Key findings

- Traditional diagnostic methods for avian influenza are limited by long turnaround times and the need for specialized equipment.
- Biosensor technologies offer opportunities for rapid, on-site detection and support for DIVA strategies.
- Electrochemical, optical, and nucleic-acid-based biosensors show promise for subtype discrimination and One Health surveillance.

## Abstract

Avian influenza (AI), particularly highly pathogenic avian influenza (HPAI), represents a serious and growing threat to global poultry production, international trade, and human health security. Control of AI is complicated by the high evolutionary rate of influenza A viruses, which drives antigenic diversity and ongoing emergence of novel strains. Effective surveillance and disease management therefore depend on timely and accurate diagnostics. While conventional methods—including virus isolation, reverse transcription-quantitative polymerase chain reaction (RT-qPCR), and enzyme-linked immunosorbent assays (ELISAs)—remain effective and widely used, they are limited by long turnaround times, the need for specialized equipment, and reliance on highly trained personnel. In addition, strict state and federal regulatory requirements restrict testing to a limited number of authorized laboratories. Although these regulations are essential for maintaining diagnostic accuracy and quality assurance, they place substantial strain on laboratory capacity during outbreaks and delay actionable results. The need for rapid, on-site decision making has driven interest in alternative diagnostic approaches, including biosensor technologies. A major limitation of current diagnostic strategies is the lack of robust DIVA (Differentiating Infected from Vaccinated Animals) capability. In countries such as the United States, where poultry vaccination against AI is not routinely practiced, the absence of DIVA-compatible diagnostics has hindered adoption of vaccination as a disease management tool, as seropositive birds and products face significant trade restrictions. Biosensor platforms capable of enabling DIVA strategies offer a potential pathway to support vaccination while preserving surveillance integrity. This review examines the current landscape of AI and HPAI diagnostics, emphasizing the limitations of traditional approaches and the opportunities presented by biosensor platforms. We evaluate electrochemical, optical, piezoelectric, and nucleic-acid-based biosensors, with particular attention to biorecognition strategies, performance metrics, field deployability, and applications supporting subtype discrimination, DIVA implementation, and One Health surveillance.

## Linked entities

- **Diseases:** avian influenza (MONDO:0018695)

## Full-text entities

- **Genes:** NEU1 (neuraminidase 1) [NCBI Gene 4758] {aka NANH, NEU, SIAL1}, VIP (vasoactive intestinal peptide) [NCBI Gene 7432] {aka PHM27}, MIP (major intrinsic protein of lens fiber) [NCBI Gene 4284] {aka AQP0, CTRCT15, LIM1, MIP26, MP26}, PBRM1 (polybromo 1) [NCBI Gene 55193] {aka BAF180, PB1, RCC, SMARCH1}, BCAR1 (BCAR1 scaffold protein, Cas family member) [NCBI Gene 9564] {aka CAS, CAS1, CASS1, CRKAS, P130Cas}
- **Diseases:** WOAH (MESH:D000820), MBCS (MESH:D009371), Ebola (MESH:D019142), dengue (MESH:D003715), seroconversion (MESH:D006679), NA (MESH:C537366), AIVs (MESH:D005585), respiratory infection (MESH:D012141), injury to (MESH:D014947), Canine influenza (MESH:D007251), HIV (MESH:D015658), infectious disease (MESH:D003141), NI (MESH:C564320), HI (MESH:C538424), Low (MESH:D009800), fatalities (MESH:C565541), COVID-19 (MESH:D000086382), infected (MESH:D007239), DIVA (MESH:D010273), HPAI viral infections (MESH:D014777)
- **Chemicals:** Cysteamine (MESH:D003543), HI (MESH:D006639), graphene oxide (MESH:C000628730), glycans (MESH:D011134), MIPs (MESH:D000082582), carbon (MESH:D002244), agar (MESH:D000362), sialic acid (MESH:D019158), Gold (MESH:D006046), Prussian blue (MESH:C000170), quartz (MESH:D011791), glucose (MESH:D005947), sialic acids (MESH:D012794), BioRender (-), europium (MESH:D005063)
- **Species:** Sus scrofa (pig, species) [taxon 9823], Meleagris gallopavo (common turkey, species) [taxon 9103], Anas platyrhynchos (duck, species) [taxon 8839], H9N2 subtype (serotype) [taxon 102796], Severe acute respiratory syndrome coronavirus 2 (no rank) [taxon 2697049], Anser (geese, genus) [taxon 8842], H3N2 subtype (serotype) [taxon 119210], Canis lupus familiaris (dog, subspecies) [taxon 9615], Phocidae (crawling seals, family) [taxon 9709], Zika virus (no rank) [taxon 64320], Gallus gallus (bantam, species) [taxon 9031], H5N1 subtype (serotype) [taxon 102793], West Nile virus (no rank) [taxon 11082], Newcastle Disease Virus [taxon 11176], Cetacea (cetaceans, infraorder) [taxon 9721], Bos taurus (bovine, species) [taxon 9913], Equus caballus (domestic horse, species) [taxon 9796], unidentified influenza virus (species) [taxon 11309], H3N8 subtype (serotype) [taxon 119211], Homo sapiens (human, species) [taxon 9606], Felis catus (cat, species) [taxon 9685], Mustela putorius furo (black ferret, subspecies) [taxon 9669], Orthomyxoviridae (family) [taxon 11308], Hepatovirus A (no rank) [taxon 12092], Viruses (acellular root) [taxon 10239], H7N9 subtype (serotype) [taxon 333278]
- **Mutations:** lysine at position 189, serine at position 155
- **Cell lines:** MDCK — Canis lupus familiaris (Dog), Spontaneously immortalized cell line (CVCL_0422)

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12938283/full.md

## References

254 references — full list in the complete paper: https://tomesphere.com/paper/PMC12938283/full.md

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Source: https://tomesphere.com/paper/PMC12938283