SMILE

Stochastic Models for the Inference of Life Evolution

Presentation

SMILE is an interdisciplinary research group gathering probabilists, statisticians, bio-informaticians and biologists.
SMILE is affiliated to the Stochastics and Biology group of LPSM (Lab of Probability, Statistics and Modeling) at Sorbonne Université (ex Université Pierre et Marie Curie Paris 06).
SMILE is hosted within the CIRB (Center for Interdisciplinary Research in Biology) at Collège de France.
SMILE is supported by Collège de France and CNRS.
Visit also our homepage at CIRB.

Recent contributions of the SMILE group related to SARS-Cov2 and COVID-19.

Directions

SMILE is hosted at Collège de France in the Latin Quarter of Paris. To reach us, go to 11 place Marcelin Berthelot (stations Luxembourg or Saint-Michel on RER B).
Our working spaces are rooms 107, 121 and 122 on first floor of building B1 (ask us for the code). Building B1 is facing you upon exiting the traversing hall behind Champollion's statue.

Contact

You can reach us by email (amaury.lambert - at - upmc.fr) or (smile - at - listes.upmc.fr).

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Publication

2020

Predicted success of prophylactic antiviral therapy to block or delay SARS-CoV-2 infection depends on the targeted mechanism

Repurposed drugs that are immediately available and have a good safety profile constitute a first line of defense against new viral infections. Despite a limited antiviral activity against SARS-CoV-2, several drugs serve as candidates for application, not only in infected individuals but also as prophylaxis to prevent infection establishment. Here we use a stochastic model to describe the early phase of a viral infection. We find that the critical efficacy needed to block viral establishment is typically above 80\%. This value can be improved by combination therapy. Below the critical efficacy, establishment can still sometimes be prevented; for that purpose, drugs blocking viral entry into target cells (or equivalently enhancing viral clearance) are more effective than drugs reducing viral production or enhancing infected cell death. When a viral infection cannot be prevented because of high exposure or low drug efficacy, antivirals can still delay the time to reach detectable viral loads from 4 days when untreated to up to 30 days. This delay flattens the within-host epidemic curve, and possibly reduces transmission and symptom severity. These results suggest that antiviral prophylaxis, even with reduced efficacy, could be efficiently used to prevent or alleviate infection in people at high risk. It could thus be an important component of the strategy to combat the SARS-CoV-2 pandemic in the months or years to come.

Publication

2018

Coagulation-transport equations and the nested coalescents

The nested Kingman coalescent describes the dynamics of particles (called genes) contained in larger components (called species), where pairs of species coalesce at constant rate and pairs of genes coalesce at constant rate provided they lie within the same species. We prove that starting from \$$rn\$$ species, the empirical distribution of species masses (numbers of genes\$$/n\$$) at time \$$t/n\$$ converges as \$$n\to\infty\$$ to a solution of the deterministic coagulation-transport equation $$ \partial_t d \ = \ \partial_x ( \psi d ) \ + \ a(t)\left(d\star d - d \right), $$ where \$$\psi(x) = cx^2\$$, \$$\star\$$ denotes convolution and \$$a(t)= 1/(t+\delta)\$$ with \$$\delta=2/r\$$. The most interesting case when \$$\delta =0\$$ corresponds to an infinite initial number of species. This equation describes the evolution of the distribution of species of mass \$$x\$$, where pairs of species can coalesce and each species' mass evolves like \$$\dot x = -\psi(x)\$$. We provide two natural probabilistic solutions of the latter IPDE and address in detail the case when \$$\delta=0\$$. The first solution is expressed in terms of a branching particle system where particles carry masses behaving as independent continuous-state branching processes. The second one is the law of the solution to the following McKean-Vlasov equation $$ dx_t \ = \ - \psi(x_t) \,dt \ + \ v_t\,\Delta J_t $$ where \$$J\$$ is an inhomogeneous Poisson process with rate \$$1/(t+\delta)\$$ and \$$(v_t; t\geq0)\$$ is a sequence of independent rvs such that \$$\mathcal L(v_t) = \mathcal L(x_t)\$$. We show that there is a unique solution to this equation and we construct this solution with the help of a marked Brownian coalescent point process. When \$$\psi(x)=x^\gamma\$$, we show the existence of a self-similar solution for the PDE which relates when \$$\gamma=2\$$ to the speed of coming down from infinity of the nested Kingman coalescent.

Upcoming seminars

Resources

Planning des salles du Collège de France.
Intranet du Collège de France.