Background: For every new drug, >10,000 candidate molecules are tested for ~15 years. This is the daily mission of thousands research teams worldwide. It is well proven that small animal imaging speeds up this work, increases accuracy and decreases costs. However, commercial imaging systems have high purchase cost, require high service contracts, special facilities and trained staff. Thus, they are affordable to only few large research centres and not to the majority of small and medium research teams internationally. There are two main reasons that urge the addressing of this problem at large scale now: Firstly, small animal imaging started in 2000 and quickly research community and pharma industry understood its value, which opened preclinical imaging market (>2.5 Bil $). Continuous evolution in medicine and biology clearly shows the need to speed up research using new tools. Asian countries rapidly invest funds in drug research, enlarging existing market. Secondly, until recently such systems were based on complicated electronics and expensive components. Evolution in detector technology, electronics, software and 3D printing, made feasible the development of benchtop imaging systems, with attractive end user price.
Materials and methods: Being an active partner of numerous international and national projects, we tried to identify the main requirements that an imaging system should have, in order to become a screening tool for daily use. Thus, we recently developed a new generation of affordable, but high-performance imaging systems, which can fulfil the daily needs of all research labs activated in preclinical research. Our technology covers the field of SPECT (Single Photon Emission Computed Tomography) and PET (Positron Emission Tomography) imaging, while an optical and x-ray imaging system is under development. The systems are based on well tested technology, including pixeliated scintillators, Position Sensitive Photomultipliers, programmable ADCs (Analog to Digital Converters) and FPGAs (Field Programmable Gate Arrays) and are connected with a standard laptop through USB and Ethernet connection. The systems are named "eyes-series" and have been already tested for fast screening of small animals injected with labeled compounds including peptides, antibodies and nanoparticles. Besides their performance, they are offered at a fraction of the cost of the commercial ones, comparable to standard lab equipment such as HPLC, gamma counter etc, opening new prospects in preclinical research. The first system is called "γ-eye™" and it is a dedicated system for imaging photons (γ-rays) which are emitted from radiolabelled biomolecules (2D-SPECT). The second system is called "β-eye™" and detects positrons (β-rays) from similar biomolecules (2D-PET). They both have dimensions which are 35x35x30cm and weight which is less that 30kgr. The spatial resolution of both systems is <2mm and their energy resolution <20%. Their sensitivity allows real time imaging for the first second post injection, while images are shown in real time during acquisition. They allow recording of fast frames, down to 1min, thus it is possible to perform fast kinetic studies. Finally, they are both provided along with a laptop that has preinstalled the required software, named "VISUAL-eyes".
Results: The technical specifications and performance evaluation of our technology will be presented. Different applications including oncology, regenerative medicine, nanomedicine and lung imaging will be given. Finally, the results of the comparison against high performance systems and a typical workflow for optimizing throughput will be demonstrated.