Your search keyword '"S. Motta"' showing total 6 results

1. Modeling the competition between lung metastases and the immune system using agents

Author

Pier Luigi Lollini, A. Palladini, Giordano Nicoletti, Marzio Pennisi, Santo Motta, Francesco Pappalardo, Patrizia Nanni, M. Pennisi, F. Pappalardo, A. Palladini, G. Nicoletti, P. Nanni, P.-L. Lollini, and S. Motta.

Subjects

Oncology, medicine.medical_specialty, Lung Neoplasms, medicine.medical_treatment, Mathematical Model, Biological Model, Agent-based modeling, Mice, Transgenic, lcsh:Computer applications to medicine. Medical informatics, Cancer Vaccines, Models, Biological, Biochemistry, Mice, Structural Biology, Internal medicine, medicine, Animals, Disseminated disease, Neoplasm Metastasis, lcsh:QH301-705.5, Molecular Biology, Mice, Inbred BALB C, Mammary tumor, business.industry, Applied Mathematics, Vaccination, Computational Biology, Mammary Neoplasms, Experimental, Reproducibility of Results, Cancer, Immunotherapy, medicine.disease, Primary tumor, Mammary Carcinoma Untreated Mouse Metastatic Burden Tumor Cell Nest Lung Metastasis Formation, Computer Science Applications, Proceedings, lcsh:Biology (General), Immune System, Cancer cell, Immunology, lcsh:R858-859.7, Experimental pathology, Female, business

Abstract

Background: The Triplex cell vaccine is a cancer cellular vaccine that can prevent almost completely the mammary tumor onset in HER-2/neu transgenic mice. In a translational perspective, the activity of the Triplex vaccine was also investigated against lung metastases showing that the vaccine is an effective treatment also for the cure of metastases. A future human application of the Triplex vaccine should take into account several aspects of biological behavior of the involved entities to improve the efficacy of therapeutic treatment and to try to predict, for example, the outcomes of longer experiments in order to move faster towards clinical phase I trials. To help to address this problem, MetastaSim, a hybrid Agent Based - ODE model for the simulation of the vaccineelicited immune system response against lung metastases in mice is presented. The model is used as in silico wetlab. As a first application MetastaSim is used to find protocols capable of maximizing the total number of prevented metastases, minimizing the number of vaccine administrations. Results: The model shows that it is possible to obtain “in silico” a 45% reduction in the number of vaccinations. The analysis of the results further suggests that any optimal protocol for preventing lung metastases formation should be composed by an initial massive vaccine dosage followed by few vaccine recalls. Conclusions: Such a reduction may represent an important result from the point of view of translational medicine to humans, since a downsizing of the number of vaccinations is usually advisable in order to minimize undesirable effects. The suggested vaccination strategy also represents a notable outcome. Even if this strategy is commonly used for many infectious diseases such as tetanus and hepatitis-B, it can be in fact considered as a relevant result in the field of cancer-vaccines immunotherapy. These results can be then used and verified in future “in vivo” experiments, and their outcome can be used to further improve and refine the model. Background The metastatic process is an extraordinary complex process. In order to colonize as econdary site and to become metastases cancer cells must complete a sequential chain of steps which include the detachment from the primary tumor, the invasion through surrounding tissues and basement membranes, the survival in the circulation, lymphatics or peritoneal space and the settlement in a distant target organ. In spite of this intrinsic inefficiency, metastases represent one of the major concerns in the clinical management of cancer. The majority of cancer mortality is associated with this disseminated disease rather than the primary tumor [1]. In most cases cancer patients with localized primary tumors have significantly better prognoses than those with disseminated tumors. Recent evidence shows that metastases can be an early event [2] and that 60% to 70% of patients have already initiated the metastatic process by the time of diagnosis. Even patients that have no evidence of tumor dissemination at diagnosis are at

Published

2010

2. In silico trial to test COVID-19 candidate vaccines: a case study with UISS platform.

Author

Russo G, Pennisi M, Fichera E, Motta S, Raciti G, Viceconti M, and Pappalardo F

Subjects

Computational Biology methods, Computer Simulation, Humans, COVID-19 immunology, COVID-19 prevention & control, COVID-19 Vaccines, Models, Immunological, SARS-CoV-2 immunology, Software

Abstract

Background: SARS-CoV-2 is a severe respiratory infection that infects humans. Its outburst entitled it as a pandemic emergence. To get a grip on this outbreak, specific preventive and therapeutic interventions are urgently needed. It must be said that, until now, there are no existing vaccines for coronaviruses. To promptly and rapidly respond to pandemic events, the application of in silico trials can be used for designing and testing medicines against SARS-CoV-2 and speed-up the vaccine discovery pipeline, predicting any therapeutic failure and minimizing undesired effects., Results: We present an in silico platform that showed to be in very good agreement with the latest literature in predicting SARS-CoV-2 dynamics and related immune system host response. Moreover, it has been used to predict the outcome of one of the latest suggested approach to design an effective vaccine, based on monoclonal antibody. Universal Immune System Simulator (UISS) in silico platform is potentially ready to be used as an in silico trial platform to predict the outcome of vaccination strategy against SARS-CoV-2., Conclusions: In silico trials are showing to be powerful weapons in predicting immune responses of potential candidate vaccines. Here, UISS has been extended to be used as an in silico trial platform to speed-up and drive the discovery pipeline of vaccine against SARS-CoV-2.

Published

2020

3. Moving forward through the in silico modeling of tuberculosis: a further step with UISS-TB.

Author

Russo G, Sgroi G, Parasiliti Palumbo GA, Pennisi M, Juarez MA, Cardona PJ, Motta S, Walker KB, Fichera E, Viceconti M, and Pappalardo F

Subjects

Antitubercular Agents therapeutic use, Immune System immunology, Isoniazid therapeutic use, Treatment Outcome, Tuberculosis drug therapy, Tuberculosis metabolism, Tuberculosis prevention & control, Tuberculosis Vaccines immunology, Computational Biology methods, Tuberculosis immunology, User-Computer Interface

Abstract

Background: In 2018, about 10 million people were found infected by tuberculosis, with approximately 1.2 million deaths worldwide. Despite these numbers have been relatively stable in recent years, tuberculosis is still considered one of the top 10 deadliest diseases worldwide. Over the years, Mycobacterium tuberculosis has developed a form of resistance to first-line tuberculosis treatments, specifically to isoniazid, leading to multi-drug-resistant tuberculosis. In this context, the EU and Indian DBT funded project STriTuVaD-In Silico Trial for Tuberculosis Vaccine Development-is supporting the identification of new interventional strategies against tuberculosis thanks to the use of Universal Immune System Simulator (UISS), a computational framework capable of predicting the immunity induced by specific drugs such as therapeutic vaccines and antibiotics., Results: Here, we present how UISS accurately simulates tuberculosis dynamics and its interaction within the immune system, and how it predicts the efficacy of the combined action of isoniazid and RUTI vaccine in a specific digital population cohort. Specifically, we simulated two groups of 100 digital patients. The first group was treated with isoniazid only, while the second one was treated with the combination of RUTI vaccine and isoniazid, according to the dosage strategy described in the clinical trial design. UISS-TB shows to be in good agreement with clinical trial results suggesting that RUTI vaccine may favor a partial recover of infected lung tissue., Conclusions: In silico trials innovations represent a powerful pipeline for the prediction of the effects of specific therapeutic strategies and related clinical outcomes. Here, we present a further step in UISS framework implementation. Specifically, we found that the simulated mechanism of action of RUTI and INH are in good alignment with the results coming from past clinical phase IIa trials.

Published

2020

4. A methodological approach for using high-level Petri Nets to model the immune system response.

Author

Pennisi M, Cavalieri S, Motta S, and Pappalardo F

Subjects

Animals, Humans, Signal Transduction physiology, Computer Graphics, Computer Simulation, Immune System immunology, Models, Biological, Software

Abstract

Background: Mathematical and computational models showed to be a very important support tool for the comprehension of the immune system response against pathogens. Models and simulations allowed to study the immune system behavior, to test biological hypotheses about diseases and infection dynamics, and to improve and optimize novel and existing drugs and vaccines. Continuous models, mainly based on differential equations, usually allow to qualitatively study the system but lack in description; conversely discrete models, such as agent based models and cellular automata, permit to describe in detail entities properties at the cost of losing most qualitative analyses. Petri Nets (PN) are a graphical modeling tool developed to model concurrency and synchronization in distributed systems. Their use has become increasingly marked also thanks to the introduction in the years of many features and extensions which lead to the born of "high level" PN., Results: We propose a novel methodological approach that is based on high level PN, and in particular on Colored Petri Nets (CPN), that can be used to model the immune system response at the cellular scale. To demonstrate the potentiality of the approach we provide a simple model of the humoral immune system response that is able of reproducing some of the most complex well-known features of the adaptive response like memory and specificity features., Conclusions: The methodology we present has advantages of both the two classical approaches based on continuous and discrete models, since it allows to gain good level of granularity in the description of cells behavior without losing the possibility of having a qualitative analysis. Furthermore, the presented methodology based on CPN allows the adoption of the same graphical modeling technique well known to life scientists that use PN for the modeling of signaling pathways. Finally, such an approach may open the floodgates to the realization of multi scale models that integrate both signaling pathways (intra cellular) models and cellular (population) models built upon the same technique and software.

Published

2016

5. Modeling the competition between lung metastases and the immune system using agents.

Author

Pennisi M, Pappalardo F, Palladini A, Nicoletti G, Nanni P, Lollini PL, and Motta S

Subjects

Animals, Female, Lung Neoplasms prevention & control, Mammary Neoplasms, Experimental therapy, Mice, Mice, Inbred BALB C, Mice, Transgenic, Neoplasm Metastasis prevention & control, Reproducibility of Results, Vaccination, Cancer Vaccines immunology, Computational Biology methods, Immune System immunology, Lung Neoplasms secondary, Mammary Neoplasms, Experimental pathology, Models, Biological

Abstract

Background: The Triplex cell vaccine is a cancer cellular vaccine that can prevent almost completely the mammary tumor onset in HER-2/neu transgenic mice. In a translational perspective, the activity of the Triplex vaccine was also investigated against lung metastases showing that the vaccine is an effective treatment also for the cure of metastases. A future human application of the Triplex vaccine should take into account several aspects of biological behavior of the involved entities to improve the efficacy of therapeutic treatment and to try to predict, for example, the outcomes of longer experiments in order to move faster towards clinical phase I trials. To help to address this problem, MetastaSim, a hybrid Agent Based - ODE model for the simulation of the vaccine-elicited immune system response against lung metastases in mice is presented. The model is used as in silico wet-lab. As a first application MetastaSim is used to find protocols capable of maximizing the total number of prevented metastases, minimizing the number of vaccine administrations., Results: The model shows that it is possible to obtain "in silico" a 45% reduction in the number of vaccinations. The analysis of the results further suggests that any optimal protocol for preventing lung metastases formation should be composed by an initial massive vaccine dosage followed by few vaccine recalls., Conclusions: Such a reduction may represent an important result from the point of view of translational medicine to humans, since a downsizing of the number of vaccinations is usually advisable in order to minimize undesirable effects. The suggested vaccination strategy also represents a notable outcome. Even if this strategy is commonly used for many infectious diseases such as tetanus and hepatitis-B, it can be in fact considered as a relevant result in the field of cancer-vaccines immunotherapy. These results can be then used and verified in future "in vivo" experiments, and their outcome can be used to further improve and refine the model.

Published

2010

6. Discovery of cancer vaccination protocols with a genetic algorithm driving an agent based simulator.

Author

Lollini PL, Motta S, and Pappalardo F

Subjects

Animals, Apoptosis drug effects, Apoptosis immunology, Cell Survival drug effects, Cell Survival immunology, Computer Simulation, Expert Systems, Mammary Neoplasms, Experimental pathology, Mice, Models, Genetic, T-Lymphocytes drug effects, T-Lymphocytes immunology, Treatment Outcome, Algorithms, Cancer Vaccines administration & dosage, Drug Therapy, Computer-Assisted methods, Immunization Schedule, Mammary Neoplasms, Experimental immunology, Mammary Neoplasms, Experimental prevention & control, Models, Immunological

Abstract

Background: Immunological prevention of cancer has been obtained in HER-2/neu transgenic mice using a vaccine that combines 3 different immune stimuli (Triplex vaccine) that is repeatedly administered for the entire lifespan of the host (Chronic protocol). Biological experiments leave open the question of whether the Chronic protocol is indeed the minimal vaccination schedule affording 100% protection, or whether shorter protocols could be applied that would result in the same efficacy. A biological solution would require an enormous number of experiments, each lasting at least one year. Therefore we approached this problem by developing a simulator (SimTriplex) which describes the immune response activated by Triplex vaccine. This simulator, tested against in vivo experiments on HER-2/neu mice, reproduces all the vaccination protocols used in the in vivo experiments. The simulator should describe any vaccination protocol within the tested range. A possible solution to the former open question using a minimal search strategy based on a genetic algorithm is presented. This is the first step toward a more general approach of biological or clinical constraints for the search of an effective vaccination schedule., Results: The results suggest that the Chronic protocol included a good number of redundant vaccine administrations, and that maximal protection could still be obtained with a number of vaccinations approximately 40% less than with the Chronic protocol., Conclusion: This approach may have important connotations with regard to translation of cancer immunopreventive approaches to human situations, in which it is desirable to minimize the number of vaccinations. We are currently setting up experiments in mice to test whether the actual effectiveness of the vaccination protocol agrees with the genetic algorithm.

Published

2006