The Role of Membrane Fluidization in the Gel-Assisted Formation of Giant Polymersomes

Greene, Adrienne C.; Henderson, Ian; Gomez, Andrew; Paxton, Walter F.; VanDelinder, Virginia; Bachand, George D.

doi:10.1371/journal.pone.0158729

Cited by 31 publications

(44 citation statements)

References 39 publications

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“…Upon hydration of the polymeric support on the glass surface, the amphiphile film mechanically swells, and is subjected to a higher surface exposure to hydration, facilitating self‐assembly into GUVs. The hydrophilic polymer is initially dissolved in water upon heating, and coated to the coverslip by drop‐casting, dip‐coating or spin‐coating, and dried. The amphiphile solution (in chloroform) is manually spread above the dehydrated hydrogel layer and is dried.…”

Section: Methodsmentioning

confidence: 99%

“…In terms of coating, the vast majority of protocols rely on the manual expertise of the operator by spreading both the gel and the amphiphilic solution using the length of a pipette tip or a needle . This type of less reproducible protocols is similarly widespread in electroformation as previously discussed.…”

Section: Methodsmentioning

confidence: 99%

“…Similar to electroformation, the concentrations of amphiphiles varies from 1–4 mg mL −1 for lipids and 3–5 mg mL −1 for polymers of M n from 3000 to 8000 g mol −1 or is sometimes not specified. Gel‐assisted hydration is fast, requires up to 1 h, contrasting with electroformation which exhibits greater variation in reported times (5 min to overnight) and generally takes several hours or longer for gentle hydration . Several gel‐assisted hydration protocols even obtain GUVs within 30 min .…”

Section: Methodsmentioning

confidence: 99%

“…Gel‐assisted hydration has only been rarely used for amphiphilic polymers. We could only find two accounts of successful GUVs formed by these methods . Both studies have use a few different polymers (PB‐ b ‐PEO, poly(ethyl ethylene)(PEE)‐ b ‐PEO, PEO‐ b ‐poly(propylene oxide)‐ b ‐PEO (PEO‐ b ‐PPO‐ b ‐PEO), and PEO‐ b ‐polydimethylsiloxane (PDMS)‐ b ‐PEO), as an initial proof that gel‐assisted hydration can be used for both triblock and diblock copolymers, with an M n between 3000 and 8000 g mol −1 and were obtained from both agarose and PVA.…”

Section: Methodsmentioning

confidence: 99%

“…Gel‐assisted hydration is still a relatively novel technique. Consequently it is not surprising that examples with amphiphilic polymers are rare and no hybrid lipid–polymer systems have been reported. Nonetheless, already a variety of lipids have been studied and this method is showing promise for the self‐assembly of all types of lipids .…”

Section: Comparison Of the Different Methodsmentioning

confidence: 99%

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Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

2019

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Self‐assembly of lipids or polymeric amphiphiles into vesicular structures has been achieved by various methods since the first generation of liposomes in the 1960s. Vesicles can be obtained with diameters from the nanometer to the micrometer regime. From the perspective of cell mimicking, vesicles with diameters of several micrometers are most relevant. These vesicles are called giant unilamellar vesicles (GUVs). Commonly used methods to form GUVs are solvent‐displacement techniques, especially since the development of microfluidics. These methodologies however, trap undesirable organic solvents in their membrane as well as other potentially undesired additives (surfactants, polyelectrolytes, polymers, etc.). In contrast to those strategies, summarized herein are solvent‐free approaches as suitable clean alternatives. The vesicles are formed from a dry thin layer of the lipid or amphiphilic polymers and are hydrated in aqueous media using the entropically favored self‐assembly of amphiphiles into GUVs. The rearrangement of the amphiphilic films into vesicular structures is usually aided by shear forces such as an alternative current (electroformation) or the swelling of water‐soluble polymeric supports (gel‐assisted hydration).

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Comparison Of the Different Methodsmentioning

confidence: 99%

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Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

2019

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Polymersomes: Fundamentals and Shape Transformation Methods

Wong

Lai

Thordarson

2023

Supramolecular Nanotechnology

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Dendrimersome Synthetic Cells Harbor Cell Division Machinery of Bacteria

et al. 2022

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as compartmentalization, transport of molecules, metabolism, growth, and ideally, replication through cell division. The latter is one of the hallmarks of life and one of the most intriguing phenomena exhibited by living organisms. [1] Beyond that, synthetic cells could comprise features that biological ones lack, such as an increased stability against environmental conditions, or much simplified programmability for desired new functions to be utilized in (bio)technological applications. [2] One obvious strategy for designing such hybrid protocells includes encapsulating components of the active cell machinery into artificial cell-like compartments. The most prominent methods involve the use of liposomes, which are lipid bilayer compartments that mimic cells with respect to their size and provide basic biochemical functionalities. [3] In these systems, reconstitution of minimal components of cell division has been demonstrated. [3b] A notable example is the MinCDE protein system, which is the spatial regulator of cell division for manyThe integration of active cell machinery with synthetic building blocks is the bridge toward developing synthetic cells with biological functions and beyond. Self-replication is one of the most important tasks of living systems, and various complex machineries exist to execute it. In Escherichia coli, a contractile division ring is positioned to mid-cell by concentration oscillations of self-organizing proteins (MinCDE), where it severs membrane and cell wall. So far, the reconstitution of any cell division machinery has exclusively been tied to liposomes. Here, the reconstitution of a rudimentary bacterial divisome in fully synthetic bicomponent dendrimersomes is shown. By tuning the membrane composition, the interaction of biological machinery with synthetic membranes can be tailored to reproduce its dynamic behavior. This constitutes an important breakthrough in the assembly of synthetic cells with biological elements, as tuning of membrane-divisome interactions is the key to engineering emergent biological behavior from the bottom-up.

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The Role of Membrane Fluidization in the Gel-Assisted Formation of Giant Polymersomes

Cited by 31 publications

References 39 publications

Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

Polymersomes: Fundamentals and Shape Transformation Methods

Dendrimersome Synthetic Cells Harbor Cell Division Machinery of Bacteria

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