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dc.contributor.author
Bachler, Simon
dc.contributor.supervisor
Dittrich, Petra S.
dc.contributor.supervisor
Krämer, Stefanie-Dorothea
dc.contributor.supervisor
Kuentz, Martin
dc.date.accessioned
2021-12-07T10:00:49Z
dc.date.available
2020-12-06T17:13:21Z
dc.date.available
2020-12-07T09:04:09Z
dc.date.available
2021-12-07T10:00:49Z
dc.date.issued
2020
dc.identifier.uri
http://hdl.handle.net/20.500.11850/454797
dc.identifier.doi
10.3929/ethz-b-000454797
dc.description.abstract
Lipid membranes serve as dynamic boundaries between the extracellular environment and the cytosol, allowing cells to compartmentalize their biochemical functions. These lipid borders are effective barriers that maintain the composition and internal compartments of cells. Lipid membranes are selectively permeable to small molecules, enabling specific transport processes that control the selective passage of substances. In the field of bottom-up synthetic biology, lipid membranes are the scaffold to create minimal cells and to mimic reactions and processes at or across their membrane. Vesicles and droplet interface bilayers are generally used to study cells as simplified models, where microfluidic platforms can improve the creation and investigation of artificial cell membranes and their compartments. Using microfluidics, it is possible to control the experimental conditions more precisely than in bulk assays, and to generate artificial membranes that are very close to the thickness and composition of cellular lipid membranes. The integration of artificial cells in microfluidic systems is still challenging and existing methods have some shortcomings. The focus of this work was first to improve current platforms for the hydrodynamic trapping of vesicles created by swelling or electroformation. We used microfluidic devices to study the interaction of both peptides and toxins with lipid membranes, observing their permeation, membranolytic effects, and pore formation. These artificial cells, however, were largely polydisperse and the encapsulation of substances remained challenging. We therefore developed a method based on microfluidic droplet arrays to address this issue, where droplets were precisely placed with a spotting device in close proximity on the surface of a plate with micro fabricated cavities. Droplets were coated with a phospholipid monolayer and droplet interface bilayers formed when two or more droplets were brought into contact. These artificial cells were monodisperse, allowing straightforward encapsulation of substances, and enabling the tailoring of the membrane composition. We initially analyzed the artificial cell membranes and compartments trough an integrated fluorescence microscope. Subsequently, we developed a protocol to separate and extract the droplets, and to interface our platform with label free matrix assisted laser desorption/ionization and liquid chromatography mass spectrometry analysis. Translocation of molecules across membranes was tailored by the addition of the pore-forming toxin alpha-hemolysin to selected droplets. Our method delivered the automated formation of one- and two-dimensional multi compartmental droplet networks. We demonstrated the effectiveness of our approach by connecting droplets containing different compounds and enzyme solutions, and performing both translocation experiments and multistep enzymatic cascade reactions across the droplet network. Moreover, we investigated the permeation of molecules across the lipid membranes, an important component in drug development to predict the absorption of substances. Example model permeants were added to donor droplets, and the permeation across symmetric and asymmetric lipid bilayer membranes to acceptor droplets was monitored. With this approach, we were able to identify the permeability coefficients. Our platform has the potential to become a tool for the screening of drug membrane permeability in the future. The embedding of membrane proteins and the fusion of cell derived vesicles with the membrane are feasible research directions. Finally, the platform may prove useful for other studies such as the three dimensional assembling towards artificial cell colonies and creating complex artificial systems for bottom-up synthetic biology.
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
Microfluidic Formation of Artificial Cell Membranes and Compartments for Permeation Studies and Cascade Reactions
en_US
dc.type
Doctoral Thesis
dc.rights.license
In Copyright - Non-Commercial Use Permitted
dc.date.published
2020-12-07
ethz.size
141 p.
en_US
ethz.code.ddc
DDC - DDC::5 - Science::570 - Life sciences
en_US
ethz.identifier.diss
26848
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::02060 - Dep. Biosysteme / Dep. of Biosystems Science and Eng.::03807 - Dittrich, Petra / Dittrich, Petra
en_US
ethz.leitzahl.certified
ETH Zürich::00002 - ETH Zürich::00012 - Lehre und Forschung::00007 - Departemente::02060 - Dep. Biosysteme / Dep. of Biosystems Science and Eng.::03807 - Dittrich, Petra / Dittrich, Petra
en_US
ethz.tag
Microfluidics
en_US
ethz.tag
Permeation
en_US
ethz.tag
Translocation
en_US
ethz.tag
Cascade Reactions
en_US
ethz.tag
LC-MS
en_US
ethz.tag
MALDI-MS
en_US
ethz.tag
Permeants
en_US
ethz.tag
Peptides
en_US
ethz.tag
Toxins
en_US
ethz.tag
Microdroplet Arrays
en_US
ethz.tag
Lipid Membranes
en_US
ethz.tag
Artificial Cell Compartments
en_US
ethz.tag
Artificial Cell Membranes
en_US
ethz.date.deposited
2020-12-06T17:13:32Z
ethz.source
FORM
ethz.eth
yes
en_US
ethz.availability
Open access
en_US
ethz.date.embargoend
2021-12-07
ethz.rosetta.installDate
2020-12-07T09:04:31Z
ethz.rosetta.lastUpdated
2022-03-29T16:28:22Z
ethz.rosetta.versionExported
true
ethz.COinS
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