Megan L. Qualls scite author profile

Multifunctional: Cyclic disulfide liposomes have been developed for the dual purposes of enhancing cellular delivery through reaction with cell‐surface thiols and facilitating liposome functionalization. These liposomes are depicted in the form of beach balls being lofted at their target cells: a scene of a warm day at the beach for a summertime issue of Chemistry—A European Journal. More information can be found in the Research Article by M. D. Best and co‐workers (DOI: 10.1002/chem.202201164).

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Demolish and Rebuild: Controlling Lipid Self-Assembly toward Triggered Release and Artificial Cells

Qualls

Sagar

Lou

et al. 2021

J. Phys. Chem. B

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The ability to modulate the structures of lipid membranes, predicated on our nuanced understanding of the properties that drive and alter lipid self-assembly, has opened up many exciting biological applications. In this Perspective, we focus on two endeavors in which the same principles are invoked to achieve completely opposite results. On one hand, controlled liposome decomposition enables triggered release of encapsulated cargo through the development of synthetic lipid switches that perturb lipid packing in the presence of disease-associated stimuli. In particular, recent approaches have utilized artificial lipid switches designed to undergo major conformational changes in response to a range of target conditions. On the other end of the spectrum, the ability to drive the in situ formation of lipid bilayer membranes from soluble precursors is an important component in the establishment of artificial cells. This work has culminated in chemoenzymatic strategies that enable lipid manufacturing from simple components. Herein, we describe recent advancements in these two unique undertakings that are linked by their reliance on common principles of lipid self-assembly.

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Bis‐Boronic Acid Liposomes for Carbohydrate Recognition and Cellular Delivery

et al. 2022

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Liposomes are effective therapeutic nanocarriers due to their ability to encapsulate and enhance the pharmacokinetic properties of a wide range of drugs and diagnostic agents. A primary area in which improvement is needed for liposomal drug delivery is to maximize the delivery of these nanocarriers to cells. Cell membrane glycans provide exciting targets for liposomal delivery since they are often densely clustered on cell membranes and glycan overabundance and aberrant glycosylation patterns are a common feature of diseased cells. Herein, we report a liposome platform incorporating bis-boronic acid lipids (BBALs) to increase valency in order to achieve selective saccharide sensing and enhance cell surface recognition based on carbohydrate binding interactions. In order to vary properties, multiple BBALs (1 a-d) with variable linkers in between the binding units were designed and synthesized. Fluorescencebased microplate screening of carbohydrate binding showed that these compounds exhibit varying binding properties depending on their structures. Additionally, fluorescence microscopy experiments indicated enhancements in cellular association when BBALs were incorporated within liposomes. These results demonstrate that multivalent BBALs serve as an exciting glycan binding liposome system for targeted delivery.

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Cyclic Disulfide Liposomes for Membrane Functionalization and Cellular Delivery

Qualls

Lou

McBee

et al. 2022

Chemistry A European J

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Liposomes are effective therapeutic delivery nanocarriers due to their ability to encapsulate and enhance the pharmacokinetic properties of a wide range of therapeutics. Two primary areas in which improvement is needed for liposomal drug delivery is to enhance the ability to infiltrate cells and to facilitate derivatization of the liposome surface. Herein, we report a liposome platform incorporating a cyclic disulfide lipid (CDL) for the dual purpose of enhancing cell entry and functionalizing the liposome membrane through thiol‐disulfide exchange. In order to accomplish this, CDL‐1 and CDL‐2, composed of lipoic acid (LA) or asparagusic acid (AA) appended to a lipid scaffold, were designed and synthesized. A fluorescence‐based microplate immobilization assay was implemented to show that these compounds enable convenient membrane decoration through reaction with thiol‐functionalized small molecules. Additionally, fluorescence microscopy experiments indicated dramatic enhancements in cellular delivery when CDLs were incorporated within liposomes. These results demonstrate that multifunctional CDLs serve as an exciting liposome system for surface decoration and enhanced cellular delivery.

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Reactive Oxygen Species (ROS) Activated Liposomal Cell Delivery using a Boronate‐Caged Guanidine Lipid

Lou

Qualls

Hudson

et al. 2022

Chemistry A European J

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We report boronate‐caged guanidine‐lipid 1 that activates liposomes for cellular delivery only upon uncaging of this compound by reactive oxygen species (ROS) to produce cationic lipid products. These liposomes are designed to mimic the exceptional cell delivery properties of cell‐penetrating peptides (CPPs), while the inclusion of the boronate cage is designed to enhance selectivity such that cell entry will only be activated in the presence of ROS. Boronate uncaging by hydrogen peroxide was verified by mass spectrometry and zeta potential (ZP) measurements. A microplate‐based fluorescence assay was developed to study the ROS‐mediated vesicle interactions between 1‐liposomes and anionic membranes, which were further elucidated via dynamic light scattering (DLS) analysis. Cellular delivery studies utilizing fluorescence microscopy demonstrated significant enhancements in cellular delivery only when 1‐liposomes were incubated with hydrogen peroxide. Our results showcase that lipid 1 exhibits strong potential as an ROS‐responsive liposomal platform for targeted drug delivery applications.

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Megan L. Qualls

Cover Feature: Cyclic Disulfide Liposomes for Membrane Functionalization and Cellular Delivery (Chem. Eur. J. 45/2022)

Demolish and Rebuild: Controlling Lipid Self-Assembly toward Triggered Release and Artificial Cells

Bis‐Boronic Acid Liposomes for Carbohydrate Recognition and Cellular Delivery

Cyclic Disulfide Liposomes for Membrane Functionalization and Cellular Delivery

Reactive Oxygen Species (ROS) Activated Liposomal Cell Delivery using a Boronate‐Caged Guanidine Lipid

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