Integrated sensor system for DNA amplification and separation based on thin film technology

This paper presents the development of a lab-on-chip, based on thin-film sensors, suitable for DNA treatments. In particular, the system performs on-chip DNA amplification and separation of double-strand DNA into single-strand DNA, combining a polydimethylsiloxane microfluidic network, thin-film electronic devices, and surface chemistry. Both the analytical procedures rely on the integration on the same glass substrate of thin-film metal heaters and amorphous silicon temperature sensors to achieve a uniform temperature distribution (within ±1 °C) in the heated area and a precise temperature control (within ±0.5 °C). The DNA separation also counts on the binding between biotinylated dsDNA and a layer of streptavidin immobilized into a microfluidic channel through polymer-brushes-based layer. This approach results in a fast and low reagents consumption system. The tested DNA treatments can be applied for carrying out the on-chip systematic evolution of ligands by exponential enrichment process, a chemistry technique for the selection of aptamers

Design and development of a lab-on-chip for biomedical analysis based on electrowetting on dielectric technique

The purpose of this thesis research project has been the development of a compact and versatile optoelectronic platform able to implement all the functionalities needed for a lab-on-chip operation. The project includes also the development of the electronics needed for the control of the system. In particular, the proposed platform includes three different modules designed for the fluid handling through the ElectroWetting On Dielectric (EWOD) technique, the thermal sample treatment and optical detection. These modules incorporate thin film microelectronic devices (such as photosensors and interferential filters for the optical detection, or heaters and temperature sensors for the sample treatments) on glass substrates connected to the electronic microcontrollers. Moreover, the use of handling techniques which avoid the use of pumps and syringes led to a portable, high-sensitive and low-power consumption lab-on-chip device. All of the modules have been designed, fabricated and tested separately. Finally, a device integrating all of the functionalities mentioned before has been designed for the development of a multifunctional platform able to perform a “true” lab-on-chip biomolecular system

Lab-on-glass system for DNA treatments

This paper presents the fabrication and testing of a lab-on-chip system suitable for treatment of DNA. It includes two main modules: a system-on-glass (SoG) and a disposable microfuidic chip. The SoG integrates, on the same glass substrate, thin film metal heaters and amorphous silicon temperature sensors to achieve a uniform temperature distribution (within 1°C) in the heated area. Two polydimethylsiloxane microfluidic chips have been developed: a PCR-Chip for DNA amplification and a dsDNA-Chip for separation and selective isolation of a ssDNA from a dsDNA. The proposed system aims therefore to develop compact, low-cost devices that can implement multiple functions in biochemical procedures. In particular, the tested bioanalytical procedures are well suited for carrying-out an on-chip SELEX process, a combinatorial chemistry technique for the selection of aptamers