Periodic Reporting for period 1 - Disc4All (Training network to advance integrated computational simulations in translational medicine, applied to intervertebral disc degeneration)
Okres sprawozdawczy: 2020-11-01 do 2022-10-31
LBP is the largest cause of morbidity worldwide, being the 4th leading cause of DALYs among Non-Communicable Diseases, already for the population between 25 and 49 years of age, according to the 2019 Global Disease Burden Report. Yet, there remains controversy as to the specific cause leading to poor treatment options and prognosis. LDD is reported to account for 50% of LBP in young adults, but the interplay of factors from genetics, environmental, cellular responses and social and psychological factors is poorly understood. Unfortunately, the integration of such data into a holistic and rational map of degenerative processes and risk factors has not been achieved, requiring creation of professional cross-competencies, which current training programmes in biomedicine, biomedical engineering and translational medicine fail to address, individually.
Disc4All aims to tackle this issue through collaborative expertise of clinicians; computational physicists and biologists; geneticists; computer scientists; cell and molecular biologists; microbiologists; bioinformaticians; and industrial partners. It provides interdisciplinary training in data curation and integration; experimental and theoretical/computational modelling; computer algorithm development; tool generation; and model and simulation platforms to transparently integrate primary data for enhanced clinical interpretations through models and simulations. Complementary training is offered in dissemination; project management; research integrity; ethics; regulation; policy; business strategy; and public and patient engagement. The Disc4All ESRs will provide a new generation of internationally mobile professionals with unique skill sets for the development of thriving careers in translational research applied to multifactorial disorders.
Specific modelling and simulation technologies have already been developed during the project, including the personalised modelling of the intervertebral disc multi-physics behaviour, and the simulation of disc cell activity in presence of different types of cell stimulators. The cell activity models are being nourished by specific cell culture models perturbed by different biochemical and mechanical environments. Thanks to extended cell regulation computational models, cell sample proteome measurements are informing about possible differential activations of cell regulation pathways, depending on the experimental perturbation. In the next steps of the project, disc cell and organ model simulations will provide synthetic data, that will be tested against the capacity to enhance real world phenotype and molecular data for advanced stratification and risk factor identification in disc degeneration and low back pain. To cope with the computational burden, calculation software is being adapted to high performance computing, for the use of distributed supercomputing infrastructures. Remarkably, the project has already delivered the first versions of the data models and integration platform, for the exploitation of the Disc4All tools by third parties. Reusable versions are planned to be shared totally or partially by the end of the project.
One main outcome of the project is a simulation platform offering access to the models and data contained therein, with the possibility of running further simulations and analyses. For the users of the platform, in other words the researchers, regulators, and doctors, the value offered is in modelling and simulation, pathway and data integration, knowledge extraction and biomarker identification. In the future, customers could come from backgrounds such as government, healthcare providers, medical equipment manufacturers, and the scientific community at large. But more immediately, the Disc4All infrastructure of data integration and systems modelling and simulations in intervertebral disc degeneration shall definitely contribute to open science, in the form of readily usable tools in scientific and clinical research.
New understanding about the origin, biology and treatment for low back pain and disc degeneration will emerge from the ‘cross-pollination’ of the input from all 15 research students until the end of the project.
Disc4All promotes the development of careers in translational research and provides a new generation of professionals with international mobility equipped with a set of unique capabilities to tackle the prevention and management of highly complex disorders through data and technology.
In particular, this project will result in beta tools for advanced diagnosis and stratification of low back pain patients, based on medical images, pain and molecular data, enhanced by model and simulation results, enabling targeted therapies.
At the socio-economic level, the Disc4All aims to raise awareness about low back pain and spinal health and promote improved self-monitoring and management, for both prevention and curation. Self-management includes the consciousness and basic knowledge of the capability to act on different factors, such as lifestyle, either preventively or to improve the outcome of a clinical therapy, through daily actions.