Zur Kurzanzeige

dc.contributor.author
Bunne, Charlotte
dc.contributor.supervisor
Krause, Andreas
dc.contributor.supervisor
Cuturi, Marco
dc.contributor.supervisor
Pelkmans, Lucas
dc.contributor.supervisor
Leskovec, Jure
dc.date.accessioned
2023-10-12T08:00:18Z
dc.date.available
2023-09-26T16:26:03Z
dc.date.available
2023-09-27T12:51:22Z
dc.date.available
2023-10-11T21:34:11Z
dc.date.available
2023-10-12T07:59:44Z
dc.date.available
2023-10-12T08:00:18Z
dc.date.issued
2023
dc.identifier.uri
http://hdl.handle.net/20.500.11850/633762
dc.identifier.doi
10.3929/ethz-b-000633762
dc.description.abstract
Modeling dynamical systems is a core subject of many scientific disciplines as it allows us to predict future states, understand complex interactions over time, and enable informed decision-making. Biological systems in particular are governed by dynamical processes, with their inherently complex and constantly changing patterns of interactions and behaviors. Single-cell biology has revolutionized biomedical research, as it allows us to monitor such systems at unprecedented scales. At the same time, it presents us with formidable challenges: While single-cell high-throughput methods routinely produce millions of data points, they are destructive assays, such that the same cell cannot be observed twice nor profiled over time. Since many of the most pressing questions in the field involve modeling the dynamic responses of heterogeneous cell populations to various stimuli, such as therapeutic drugs or developmental signals, there is a pressing need to provide computational methods that can circumvent that limitation and re-align these unpaired measurements. Optimal transport (OT) has emerged as a major opportunity to fill in that gap in silico as it allows us to reconstruct how a distribution evolves, given only access to distinct snapshots of unaligned data points. Classical OT methods, however, do not generalize to unseen samples. Yet, this is crucial when, for example, predicting treatment responses of incoming patient samples or extrapolating cellular dynamics beyond the measured horizon. By harnessing the theoretical constructs of OT, this thesis explores and develops neural static and dynamic optimal transport schemes for elucidating the intricate dynamics of biological populations. It encapsulates an array of algorithmic frameworks, with contributions to both the understanding and prediction of population dynamics: First, we derive static neural optimal transport schemes capable of learning a map between the unpaired distributions of unperturbed and perturbed cells. These models excel at predicting single-cell responses to varying perturbations, such as cancer drug screens, and generalize the inference of treatment outcomes to unobserved cell types and patients. This has significant implications for personalized medicine, as it allows for the prediction of treatment responses for new patients in large-scale clinical studies. Second, we explore dynamic neural optimal transport formulations that leverage the connections of OT to partial differential equation and gradient flows through the Jordan-Kinderlehrer-Otto scheme, as well as stochastic differential equations and optimal control through the diffusion Schrödinger bridge. These methods then serve as robust tools for reconstructing stochastic and continuous-time dynamics from marginal observations, allowing us to dissect fine-grained and time-resolved cellular mechanisms. This thesis connects a variety of seemingly unrelated concepts into a unified framework, and the presented methodologies offer a computational and mathematical foundation for modeling of cellular dynamics. This provides new avenues to understand cellular heterogeneity, plasticity, and response landscapes. Such neural parameterizations of static and dynamic OT that allow for out-of-sample inference lay the groundwork for exciting opportunities to make novel biological discoveries, infer personalized therapies from single-cell patient samples, and push the boundaries of regenerative medicine.
en_US
dc.format
application/pdf
en_US
dc.language.iso
en
en_US
dc.publisher
ETH Zurich
en_US
dc.rights.uri
http://rightsstatements.org/page/InC-NC/1.0/
dc.title
Neural Optimal Transport for Dynamical Systems
en_US
dc.type
Doctoral Thesis
dc.rights.license
In Copyright - Non-Commercial Use Permitted
dc.date.published
2023-09-27
ethz.title.subtitle
Methods and Applications in Biomedicine
en_US
ethz.size
239 p.
en_US
ethz.code.ddc
DDC - DDC::0 - Computer science, information & general works::004 - Data processing, computer science
en_US
ethz.code.ddc
DDC - DDC::5 - Science::570 - Life sciences
en_US
ethz.identifier.diss
29594
en_US
ethz.publication.place
Zurich
en_US
ethz.publication.status
published
en_US
ethz.leitzahl
ETH Zürich::00002 - ETH Zürich::00012 - Lehre und Forschung::00007 - Departemente::02150 - Dep. Informatik / Dep. of Computer Science::02661 - Institut für Maschinelles Lernen / Institute for Machine Learning::03908 - Krause, Andreas / Krause, Andreas
en_US
ethz.leitzahl.certified
ETH Zürich::00002 - ETH Zürich::00012 - Lehre und Forschung::00007 - Departemente::02150 - Dep. Informatik / Dep. of Computer Science::02661 - Institut für Maschinelles Lernen / Institute for Machine Learning::03908 - Krause, Andreas / Krause, Andreas
en_US
ethz.date.deposited
2023-09-26T16:26:03Z
ethz.source
FORM
ethz.eth
yes
en_US
ethz.availability
Open access
en_US
ethz.rosetta.installDate
2023-09-27T12:51:24Z
ethz.rosetta.lastUpdated
2024-02-03T05:11:38Z
ethz.rosetta.versionExported
true
ethz.COinS
ctx_ver=Z39.88-2004&rft_val_fmt=info:ofi/fmt:kev:mtx:journal&rft.atitle=Neural%20Optimal%20Transport%20for%20Dynamical%20Systems&rft.date=2023&rft.au=Bunne,%20Charlotte&rft.genre=unknown&rft.btitle=Neural%20Optimal%20Transport%20for%20Dynamical%20Systems
 Printexemplar via ETH-Bibliothek suchen

Dateien zu diesem Eintrag

Thumbnail

Publikationstyp

Zur Kurzanzeige