In this way, metastases may be formed, even after the main tumour was treated successfully.
It is difficult to detect cancer cells in the blood at an early stage. About one malignant cell is encountered per billion of healthy cells.
Researchers of KIT and the Center for Nanotechnology (CeNTech), Münster, have now developed a clinical method to reliably detect and isolate single cancer cells in blood samples in cooperation with the University Hospital of Hamburg-Eppendorf (UKE).
“Detection of cancer cells in blood in the early stage of a disease is difficult, because concentrations of the cancer cells are extremely small,” Harald Fuchs, Section Head of the KIT Institute of Nanotechnology (INT), holder of a chair at the Physical Institute of the University of Münster (WWU), and Scientific Director of the Center for NanoTechnology (CeNTech), Münster, explains.
“We are searching for the needles in the haystack.”
The number of extracted tumour cells allows conclusions to be drawn with respect to the success of therapy and the future course of the disease.
Genetic analysis of cells allows therapies to be adapted to the type of cancer to be treated.
His young investigators group of INT is largely involved in the development work.
“In addition, we can sample suspicious cells undamaged and study them in more detail.”
Medical tests of patient blood samples were carried out by the team of Klaus Pantel of the University Hospital of Hamburg-Eppendorf.
Moreover, the newly developed method can be transferred to all applications, where rare cells in blood or other body liquids have to be isolated.
The main component of the new method is a microarray platform.
By means of polymer pen lithography, a surface is provided with a microscopically small structure using a plastic die.
The target cells adhere to these structures.
The blood sample to be investigated is injected into a flat microchannel that crosses the platform.
As a maximum number of target cells is to contact the array, a fishbone-shaped structure at the top of the channel stirs up the passing liquid.
To prevent the arrays, i.e. the locks, from having to be exchanged for every application, the scientists provide all target cells with a general key: The biotin vitamin.
In advance, this vitamin couples to the surface of the target cells via specific antibodies.
“Our concept still is in the development phase and, hence, not fully optimised. Its sensitivity, however, partly exceeds that of known standard methods already. In addition, medical fine diagnosis of the cells is facilitated,” Harald Fuchs emphasises.
The researchers are now working on a prototype method that can be used at the hospital.