We identify target and off-target proteins
of any small molecule on a proteome-wide scale
Our technologies allow to identify target and off-target proteins of any drug through a systematic analysis and ranking of very large protein databases, such as the whole available human structural proteome.
Our tools have unique potentialities in identifying drug binding sites on protein 3D-structures whether or not they are occupied, strongly distorted, or even completely closed, compared to a suitable conformation for the binding.
Developing and using new computational technologies for clinical pharmacology
Clarifying ADVERSE EFFECTS
Adverse effects arising from aspecific drug-target interactions may be predicted and/or clarified at a biomolecular level through direct identification of the off-target proteins on a proteome-wide scale. The whole available human structural proteome can be screened by SPILLO-PBSS in affordable computation time.
Advancing PRECISION MEDICINE
Dose limitation and discontinuation of treatments due to adverse effects may expose patients to major health risks. A clearer drug-target interactions map can be generated by SPILLO-PBSS, aimed at designing safer and more effective therapies, according to individual patient’s variations.
New drug-target interactions responsible for additional positive effects of a therapeutic agent may be successfully identified by SPILLO-PBSS. Polypharmacological therapies able to interfere with multiple targets of the same disease network may then be selected to improve the efficacy of the treatment.
Clarifying THERAPEUTIC EFFECTS
If the mechanism of action of a therapeutic agent is not well-defined or still unknown, a screening of the whole available human structural proteome by SPILLO-PBSS can be crucial to identify the primary target responsible for the reported effects of that molecule.
Facilitating DRUG REPOSITIONING
SPILLO-PBSS may find off-target proteins involved in pathological network other than that to which the primary target belongs, thus providing the opportunity for using known drugs for new indications, maximizing in this way the potential of a drug.
Addressing RARE DISEASES
SPILLO-PBSS can be a valuable resource for neglected- and rare-diseases research in the effort to identify opportunities of drug repositioning, which represents a cheaper and faster alternative to traditional drug discovery.
Developing and using new computational technologies for drug R&D
A brief introduction to SPILLOproject
SPILLOproject was founded by Dr. Alessandro Di Domizio in 2016 with the goal of improving human health and advancing disease research, including rare and neglected diseases, by developing and using innovative computational technologies. It is located in Cinisello Balsamo, Milan, Italy, and it is carried on by its founder together with an interdisciplinary team of experts.
Our in silico methodologies represent a unique and valuable resource (see peer-reviewed article in JCC) for all areas where molecular recognition via protein-ligand interactions plays a key role, including (among others) drug R&D, clinical pharmacology, precision medicine and toxicology.
We provide services to drastically reduce the cost of the drug discovery and development process, while increasing the probability of success of new therapies. We collaborate with private and public research centers, academia, pharmaceutical and biotech companies. We are at your disposal to answer any question concerning possible applications of our technologies to problems of your interest, and to carry out preliminary feasibility studies.
Comparison with traditional structure-based approaches
Application of SPILLO-PBSS to industrial biocatalysis
Rational polypharmacology drug design AND Optimization of drug safety profile
Main applications of SPILLO-PBSS to the drug R&D process
A short description of SPILLO-PBSS