The browser you are using is not supported by this website. All versions of Internet Explorer are no longer supported, either by us or Microsoft (read more here:

Please use a modern browser to fully experience our website, such as the newest versions of Edge, Chrome, Firefox or Safari etc.

ERC grant for one-step Covid detection

The corona virus. Picture: Mostphotos.
Christelle Prinz’ project developing a test that quickly detects viruses in the body receives an ERC proof of concept – innovation money from the European Research Council. Picture: Mostphotos.

Christelle Prinz, professor of solid state physics and affiliated to NanoLund, receives 150,000 euros to further develop research results that are considered to have great innovation potential by the European Research Council.

For several years, physicist Christelle Prinz has developed nanotechnology to diagnose and study diseases in various ways, such as cancer. In an ongoing ERC project, she and her colleagues are developing a method to study cancer cells at the individual level. For this project, she now receives extra funding.

The purpose, though, is completely different: One of the techniques used to study cells has proven useful for detecting viruses – including the one causing Covid-19.

Unlike today’s PCR test, results can come after a few minutes, according to Prinz. In addition, they become cheaper to manufacture and read. If everything goes according to plan, a test like this could be used in a year at the earliest.

Easy testing before a work shift

“There is a great need for testing even after the vaccination has started. For example, that home care staff or others who work with the elderly can test themselves quickly and easily before they go out on a work shift”, says Christelle Prinz.

The European Research Council Magazine states: The WHO recommendation to test, trace, and isolate requires fast and wide-scale testing of the SARS-CoV-2 virus. The sampling and processing complexity of currently available tests pose a challenge to our healthcare systems. Widely used polymerase chain reaction (PCR) tests take several hours and require advanced laboratory equipment, which adds to the difficulty of tracing and isolating patients rapidly.

The goal: efficient, rapid, one-step tests

Christelle Prinz will build on her previous findings and apply a method developed as part of research funded by her earlier ERC Consolidator Grant, which could help enable a single-step detection of the virus. Her team will use low-cost reagents technology to develop more affordable tests than those currently available on the market. Their goal is to develop rapid, one-step tests with efficiency superior to the antigen tests and comparable to PCR tests.

By detecting the virus directly, the test will identify only active infections. Its high accuracy would cut-down false-positive and false-negative results, while easy usage aims to eliminate the assay complexity. It could facilitate smoother workflows in the laboratory and point-of-care diagnostics. The project team also foresees that this technology could be extendable to the detection of other viruses. Its affordability should make it widely used and accessible to developing countries.


About Christelle Printz and the ERC proof of concept

Christelle Prinz is affiliated with NanoLund, a Strategic Research Area funded by the Swedish Government and Sweden’s largest research environment for nanoscience and nanotechnology. She obtained her Ph.D. in polymer physics from Strasbourg University and further acquired her scientific knowledge as a postdoctoral researcher at Princeton University. She is currently a leader of the research group at Lund University that investigates the interactions between nanomaterials and living matter on the cellular and organism level.

Project: One-step switchable fluorescent probe assay for direct virus detection (1-SWITCH)
ERC Funding: € 150.000
2015 ERC Consolidator Grant: Deciphering cell heterogeneity in tumors using arrays of nanowires to controllably poke single cells in longitudinal studies

Link to the NanoPokers research project description on the ERC Consolidator Grant website