Russian Scientists Present New Application for Nanophotonic Sensor

A joint research team from HSE, Skoltech, MPGU and MISIS has developed a compact sensor for biochemical analysis, opening up a new frontier in the development of the ‘lab-on-a-chip’. Using bovine serum albumin film as an example, the researchers proved that the chip surface can be adapted for selective analysis of multicomponent solutions. Along with enabling accurate blood tests with only 3 to 5 microliters of blood, the chip will help doctors to detect specific disease markers. The study was published in Analytical Chemistry.

Almost every medical examination starts with a test and, most often, a blood count showing haemoglobin, red and blood cell levels, etc. Sometimes only one component is required to assess a patient’s condition. For example, you might need to determine the number of exosomes—microscopic extracellular vesicles which in large quantities may be a sign of cancer.

For test purposes, laboratories use sensitive sensors with a surface covered in a special coating that binds only to specific exosomes and picks them out from the solution for analysis. Some devices require a multi-step procedure, including coating application and quality checks on another instrument. The authors showed a way to simplify the test by checking the surface quality using on-chip sensors.

To do this, they applied thin protein films on the chip substrate and performed a series of experiments. The chip consists of three parts: microfluidic channels carrying the substance, a silicon nitride substrate beneath the coating, and photonic integrated circuits (PICs) for measuring the substance’s optical density. The microfluidic channel is located above the sensitive part of the PIC devices.

In the experiments, the researchers deposited protein and tannic acid films layer by layer onto the sensitive surface of the PICs. After pumping bovine serum albumin through the microfluidic channels, they washed out the excess albumin with deionised water, pumped in tannic acid, reapplied the protein coating and analysed the deposition process for each layer in real time using optical readings from the interferometer.

The team will continue to work on the ‘lab-on-a-chip’—a device that can analyse several components simultaneously using a minimum volume of biological samples, such as a drop of blood. To do this, the researchers plan to increase the number of PICs on the chip.

IQ