The ISBGroup Blog

Last week, I had the honor of giving the concluding keynote lecture at the event “Data-driven mechanistic modelling in life sciences”. This follows a trend of being invited to give more and more keynote and plenary lectures at events, for which I am very grateful. Such longer lectures also give me the chance to expand a little bit more on my point-of-view. The focus of this particular workshop is also something I am very keen to promote, since I think that this particular overlap (mechanistic and data-driven modelling) is under-represented in many communities and conferences.

The centrality of this overlap is actually seen even in our group logo (Fig A). a) The fact that it has an open non-black box, represents the fact that we do mechanistic modelling. b) The data-driven aspect of our models is represent by the purple core in the middle, which represents the fact that we always look for core predictions. Core predictions are predictions that are well-determined from the current prior knowledge and data, even when taking all uncertainties in data and prior knowledge into account.

While I personally think that this is the way to work, and while we have a very well-established workflow for how to develop models in this fashion, mechanistic modelling and data-driven modelling are unfortunately often done in two disjoint communities, with too little overlap (Fig B). Mechanistic modelling often results in mere simulation-based results, which have not been validated using independent data, i.e. data that has not been used to train the model. This is often the case for e.g. PDE and agent-based models, but also common in e.g. theoretical ecology, theoretical biology, etc. It was therefore encouraging too see that one of the presentations at the workshop (by Joshua Bull) looked at spatial models, and on how to quantify the comparison between simulations and data also for spatial models. Data-driven modelling is too often interpreted to mean only machine-learning, narrow AI, and other black-box modelling techniques. While these are big and very hyped communities and approaches at the moment, they are not the only techniques that can be used to do data-driven modelling. In other words, while these black-box models include important techniques, which are useful if one has standardized large-scale data, they also have critical short-comings. Black-box models e.g. have big problems incorporating the type of data that is present in most biological papers, including the prior that is knowledge available. For these reasons, explainability and trustworthiness are challenges. I therefore think that hybrid modelling is the way forward (see e.g. this review, and this example). At the conference, there was also an excellent opening keynote of day 2, by Alvaro Köhn-Luque, which showed some additional and interesting examples of hybrid models.

Christian Simonsson

Titel: Mathematical modelling of diffuse liver disease

Opponents: Jan Boren and Matthias König

Date: 2023-03-01

Abstract: Christian has worked on constructing mathematical models in the context of NAFLD treatment and disease progression. One project has been focusing on creating a minimal mathematical model capable of simulating different dietary interventions, such low carb high fat diet (LCHF), and high fructose (HC) diets. To better understand treatment connection to changes in lipid fluxes. The second project has focused on determining liver function before hepatectomy, which is the only treatment option for HCC and liver metastasis. The two different projects have focused on each end of the NAFLD disease spectra, and the coming project will focus on modelling of non-alcoholic steatohepatitis (NASH)

Tilda Herrgårdh 

Titel: Hybrid modelling for diabetes and stroke prevention

Opponents: Maria Kjellsson, Anna Nordström

Date: 2023-03-02

Abstract: The long-term goal that the thesis will be a part of is to have a tool for prevention of metabolic and cardiovascular diseases, particularly stroke and its common precursor diabetes.  The plan is to use a digital twin and hybrid modelling. A digital twin can be used to make personalized predictions for different scenarios – lifestyle changes, diets, drugs, etc. – that can then be evaluated and compared. These predictions can include the long-term dynamics of different risk factors relevant for cardiovascular disease, such as BMI or fasting plasma glucose, or short term dynamics such as meal response glucose. These predictions can for example be used to understand the dynamics behind disease progression and to get continuous updated on progress of the changes made in real life, which can hopefully increase medical pedagogics and motivation. The long-term predictions of risk factors can be used in a hybrid modelling scheme as input in a machine learning model to get your risk score for having a stroke within a certain time span. The thesis covers the first steps towards, and a first example of the idea described above, as well as the development of models describing some of the different mechanisms relevant to diabetes and stroke progressions that can later be used in a comprehensive model of the entire progression. 

Nicolas Sundqvist

Titel: Systems modelling of human metabolism: Methods for 13C metabolic flux analysis and applications to the brain

Opponents: Elizabeth Klint, Dr. Katharina Nöh, Dr. Joao Duart

Date: 2023-01-17

Abstract: Nicolas has worked on constructing a mathematical model that can explain the mechanism that regulate the metabolism in the brain. This mathematical model explains what the cerebral metabolic response looks like in response neuronal activity induced by a visual stimulus. Furthermore, the work also includes how these mechanisms for the metabolic response connect to the mechanisms that of the neurovascular coupling. This work has resulted in a manuscript recently accepted for publication and will formed a base for future modelling endeavours. Additionally, Nicolas has worked with modelling intracellular metabolic fluxes using measurements of 13C isotope labels. A lot of this work have gone into method development for modelling stoichiometric models for 13C metabolic flux analysis (MFA) and has resulted in a publication where we present a method for validating such models when there is an uncertainty with respect to experimental measurement uncertainty. The plan for the continued work of Nicolas’ doctoral studies is to apply the methodologies for 13C MFA to a system for studying neurodegenerative diseases in neurological cell lines. As well as to investigate the mechanisms of the regulation of oxygen metabolism with respect to activity in different types of neuronal cells. 

Digital twins will now be tested in real health care environments, in an EU-financed project. Gunnar is the project manager of STRATIF-AI, which has been granted SEK 65 million over a four-year period by Europe Horizon (the European Commission). The project is linked to stroke research, but the digital twins method is expected to have many different applications.

Read more about the project HERE

We recently published a paper detailing mechanisms of insulin signaling and type 2 diabetes at multiple levels in rat adipocytes. In this paper, we present a model that can simulate weight changes on a wholebody level, and propagate the effect of weight related insulin resistance down to the cellular and tissue level. 

You find the link to the full paper HERE