Leuko-polymersomes

Hammer, Daniel A.; Robbins, Gregory P.; Haun, Jered B.; Lin, John J.; Wei, Qi; Smith, Lee A.; Ghoroghchian, P. Peter; Therien, Michael J.; Bates, Frank S.

doi:10.1039/b717821b

Cited by 82 publications

(101 citation statements)

References 52 publications

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“…In contrast to previous studies, the adhesion strength did not depend on the amount of biotinylated block copolymer, but rather increased linearly with the surface-density of the binding ligand, because the flexible polymer chains are buried underneath the coat of neutravidin (Figure 3(b) and 3(c)). Under physiological flow rates, such decorated vesicles do adhere to surfaces coated with inflammatory adhesion molecules P-selectin (to which sLe x binds) and ICAM-1 [45,49], as well as to inflamed endothelium [49], indicating possible applications as a targeted drug-delivery system. Although cell-specific targeting in vitro was shown with polymersomes that were surface-modified by a biotin-streptavidin approach [20,34], such polymersomes would not be of use in vivo studies because streptavidin is known to block essential immune reactions in the human body [50].…”

Section: Aminementioning

confidence: 99%

“…Ligands are bound indirectly by biotin-streptavidin-biotin interactions to the polymersome surface. The modification of block copolymers with biotin has been performed either by N,N'-dicyclohexylcarbodiimide/4-(dimethylamino)pyridine-activated esterification [17,20,34,35] or by preactivation of the terminal hydroxyl functionality by tresyl chloride [44] or 4-fluoro-3-nitrobenzoic acid [36,45] and subsequent reaction with biocytin [33,36]. Both the esterification and the tresylation method resulted in a good yield of biotin modified polymer, which is essential for streptavidin and thus ligand binding after self-assembly of the polymersome.…”

Section: Aminementioning

confidence: 99%

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Functionalization of Block Copolymer Vesicle Surfaces

et al. 2011

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Abstract:In dilute aqueous solutions certain amphiphilic block copolymers self-assemble into vesicles that enclose a small pool of water with a membrane. Such polymersomes have promising applications ranging from targeted drug-delivery devices, to biosensors, and nanoreactors. Interactions between block copolymer membranes and their surroundings are important factors that determine their potential biomedical applications. Such interactions are influenced predominantly by the membrane surface. We review methods to functionalize block copolymer vesicle surfaces by chemical means with ligands such as antibodies, adhesion moieties, enzymes, carbohydrates and fluorophores. Furthermore, surface-functionalization can be achieved by self-assembly of polymers that carry ligands at their chain ends or in their hydrophilic blocks. While this review focuses on the strategies to functionalize vesicle surfaces, the applications realized by, and envisioned for, such functional polymersomes are also highlighted.

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Section: Aminementioning

confidence: 99%

Section: Aminementioning

confidence: 99%

Functionalization of Block Copolymer Vesicle Surfaces

et al. 2011

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“…leuko-polymersomes. Thus, functionalizing the terminal groups on the outer shell of vesicles via avidin-biotin chemistry, Hammer et al attached adhesion ligands, selectins and integrins, mimicking the two critical adhesion pathways that leukocytes utilize to achieve adhesion in the fast fluid flow of blood vessels [73]. These leuko-polymersomes achieved specific adhesion at hydrodynamic flow rates at which leukocytes adhere.…”

Section: Active Targeted Nanoassembliesmentioning

confidence: 99%

Multifunctional nanoassemblies of block copolymers for future cancer therapy

Cabral

Kataoka

2010

Science and Technology of Advanced Materials

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Nanoassemblies from amphiphilic block copolymers are promising nanomedicine platforms for cancer diagnosis and therapy due to their relatively small size, high loading capacity of drugs, controlled drug release, in vivo stability and prolonged blood circulation. Recent clinical trials with self-assembled polymeric micelles incorporating anticancer drugs have shown improved antitumor activity and decreased side effects encouraging the further development of nanoassemblies for drug delivery. This review summarizes recent approaches considering stimuli-responsive, multifunctionality and more advanced architectures, such as vesicles or worm-like micelles, for tumor-specific drug and gene delivery.

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“…The shells of these microcarriers are sufficiently robust to act as a protective barrier, and adequately permeable for the controlled exchange of reagents with an external solution (22). Furthermore, the permselectivity of the shells can be readily tuned (20,21,(23)(24)(25). By functionalizing the shell's outer surface, these microcarriers can bind to an underlying substrate (20).…”

mentioning

confidence: 99%

“…In the ensuing discussion, we envision these synthetic systems to be polymeric microcapsules synthesized via the layer-by-layer (LbL) approach (16)(17)(18) or "polymersomes" (19)(20)(21). Such objects provide ideal platforms for creating "artificial cells," which could be tailored to exhibit a range of cellular functionality (16).…”

mentioning

confidence: 99%

Designing communicating colonies of biomimetic microcapsules

Kolmakov¹,

Yashin²,

Levitan

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Using computational modeling, we design colonies of biomimetic microcapsules that exploit chemical mechanisms to communicate and alter their local environment. As a result, these synthetic objects can self-organize into various autonomously moving structures and exhibit ant-like tracking behavior. In the simulations, signaling microcapsules release agonist particles, whereas target microcapsules release antagonist particles and the permeabilities of both capsule types depend on the local particle concentration in the surrounding solution. Additionally, the released nanoscopic particles can bind to the underlying substrate and thereby create adhesion gradients that propel the microcapsules to move. Hydrodynamic interactions and the feedback mechanism provided by the dissolved particles are both necessary to achieve the collective dynamics exhibited by these colonies. Our model provides a platform for integrating both the spatial and temporal behavior of assemblies of "artificial cells," and allows us to design a rich variety of structures capable of exhibiting complex, cooperative behavior. Due to the cell-like attributes of polymeric microcapsules and polymersomes, material systems are available for realizing our predictions.ne of the hallmarks of biological cells and microorganisms is their ability to share information and through this communication, perform concerted functions; herein, we use computational modeling to design synthetic microcapsules that mimic this basic biological behavior. To perform this study, we first devise a set of chemical mechanisms that enable a pair of permeable, three-dimensional capsules to create adhesion gradients on a substrate and thereby undergo coordinated, autonomous motion. Implemented in a colony of neighboring capsules, these same chemical mechanisms give rise to self-propelled "snakes" and other self-organized structures. Finally, we consider two distinct colonies of microcapsules and identify scenarios where capsules from the second colony follow the chemical trail left by species from the first. In this manner, the system resembles ant-tracking behavior (1). These studies illustrate how basic concepts from biological signaling can be used to create assemblies of microscopic objects that communicate through external cues and thus exhibit complex, collective behavior. Ultimately, the findings could enable the fabrication of small-scale, interactive devices that cooperate to perform specified functions (e.g., sensing, selforganizing, and self-actuation).Researchers in the physical sciences communities have become fascinated with creating self-propelled, microscopic objects; a recent review article (2) describes examples where chemical reactions (3-7) and external fields (8, 9) provide the "fuel" that drives these synthetic particles. On the other hand, scientists in the biological communities are attempting to develop theoretical and computational models to characterize biochemical signaling processes occurring between cells or microorganisms that lead to their collective...

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Leuko-polymersomes

Cited by 82 publications

References 52 publications

Functionalization of Block Copolymer Vesicle Surfaces

Functionalization of Block Copolymer Vesicle Surfaces

Multifunctional nanoassemblies of block copolymers for future cancer therapy

Designing communicating colonies of biomimetic microcapsules

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