Abstract: A microfluidic device for generating microbubbles includes a substrate and a microfluidic channel embedded in the substrate. The microfluidic channel includes a plurality of fluid inlets, at least one bubble formation outlet having a nozzle with an adjustable diameter, and a flow focusing junction in fluid communication with the plurality of fluid inlets and the bubble formation outlet. A method for mass producing monodisperse microbubbles with a microfluidic device includes supplying a flow of dispersed phase fluid into a first fluid inlet of a microfluidic channel, supplying a flow of continuous phase fluid into a second fluid inlet of the microfluidic channel, and adjusting a diameter of a nozzle to obtain a plurality of monodisperse microbubbles having a specified diameter.

Abstract: A microfluidic device for generating mi-crobubbles includes a substrate and a microfluidic channel embedded in the substrate. The microfluidic channel includes a plurality of fluid inlets, at least one bubble formation outlet having a nozzle with an adjustable diameter, and a flow focusing junction in fluid communication with the plurality of fluid inlets and the bubble formation outlet. A method for mass producing monodisperse microbubbles with a microfluidic device includes supplying a flow of dispersed phase fluid into a first fluid inlet of a microfluidic channel, supplying a flow of continuous phase fluid into a second fluid inlet of the microfluidic channel, and adjusting a diameter of a nozzle to obtain a plurality of monodisperse microbubbles having a specified diameter.

Abstract: The present invention includes a composition comprising at least one oleosin-like protein. The present invention also includes a composition comprising a vesicle comprising at least one oleosin-like protein.

Abstract: Provided are polymer vesicles comprising polymersomes, a radiofrequency absorbing moiety, a protein or a polysaccharide associated with the inner leaflet of the membrane and a therapeutic or diagnostic cargo. The invention also concerns the use of these polymer vesicles for selective electromagnetic energy-induced delivery of therapeutic or diagnostic agents.

Abstract: The present invention includes a composition comprising at least one oleosin-like protein. The present invention also includes a composition comprising a vesicle comprising at least one oleosin-like protein.

Abstract: Disclosed are methods of controllably permeabilizing polymersomes. Such methods are useful in permeabilizing polymersomes so as to effect controlled release of therapeutic or imaging agents to a particular location. Also disclosed are systems for controllably delivering various agents to particular locations via polymersomes and related polymersome-based methods for treating diseases and for imaging.

Abstract: The present invention provides biocompatible vesicles comprising semi-permeable, thin-walled encapsulating membranes which are formed in an aqueous solution, and which comprise one or more synthetic super-amphiphilic molecules. When at least one super-amphiphile molecule is a block copolymer, the resulting synthetic vesicle is termed a “polymersome.” The synthetic, reactive nature of the amphiphilic composition enables extensive, covalent cross-linking of the membrane, while maintaining semi-permeability. Cross-linking of the polymer building-block components provides mechanical control and long-term stability to the vesicle, thereby also providing a means of controlling the encapsulation or release of materials from the vesicle by modifying the composition of the membrane. Thus, the encapsulating membranes of the present invention are particularly suited for the reliable, durable and controlled transport, delivery and storage of materials.

Abstract: Disclosed are stabilized polymersomes having layer structures. Such stabilized polymersomes are, in some embodiments, biocompatible, and are capable of enhanced, sustained release of agents. Also disclosed are related methods for synthesizing such stabilized polymersomes and methods for using such polymersomes for delivery of therapeutic, imaging, and various other agents.

Abstract: Provided are polymer vesicles comprising polymersomes, a radiofrequency absorbing moiety, a protein or a polysaccharide associated with the inner leaflet of the membrane and a therapeutic or diagnostic cargo. The invention also concerns the use of these polymer vesicles for selective electromagnetic energy-induced delivery of therapeutic or diagnostic agents.

Abstract: The instant invention concerns compositions comprising polymersomes, visible or near infrared emissive agents, and optionally a targeting moiety associated with a surface of the polymersome. The invention also relates to use of these compositions in the treatment of disease and in imaging methodology.

Abstract: The invention concerns a block copolymer of polyethylene oxide and polycaprolactone, the polyethylene oxide having a number average molecular weight from about 2.0 to about 3.8 kD, the block copolymer having a fraction of polyethylene oxide of from about 11.8 to 18.8 percent by weight. The invention also concerns polymersomes made from such copolymers and to methods of making the polymersomes.

Abstract: The present invention provides biocompatible vesicles comprising semi-permeable, thin-walled encapsulating membranes which are formed in an aqueous solution, and which comprise one or more synthetic super-amphiphilic molecules. When at least one super-amphiphile molecule is a block copolymer, the resulting synthetic vesicle is termed a “polymersome.” The synthetic, reactive nature of the amphiphilic composition enables extensive, covalent cross-linking of the membrane, while maintaining semi-permeability. Cross-linking of the polymer building-block components provides mechanical control and long-term stability to the vesicle, thereby also providing a means of controlling the encapsulation or release of materials from the vesicle by modifying the composition of the membrane. Thus, the encapsulating membranes of the present invention are particularly suited for the reliable, durable and controlled transport, delivery and storage of materials.

Abstract: The present invention provides biocompatible vesicles comprising semi-permeable, thin-walled encapsulating membranes which are formed in an aqueous solution, and which comprise one or more synthetic super-amphiphilic molecules. When at least one super-amphiphile molecule is a block copolymer, the resulting synthetic vesicle is termed a “polymersome.” The synthetic, reactive nature of the amphiphilic composition enables extensive, covalent cross-linking of the membrane, while maintaining semi-permeability. Cross-linking of the polymer building-block components provides mechanical control and long-term stability to the vesicle, thereby also providing a means of controlling the encapsulation or release of materials from the vesicle by modifying the composition of the membrane. Thus, the encapsulating membranes of the present invention are particularly suited for the reliable, durable and controlled transport, delivery and storage of materials.