Methods, systems, and devices are disclosed for fabricating and implementing nanoscale and microscale structured carriers to provide guided, targeted, and on-demand delivery of molecules and biochemical substances for a variety of applications including diagnosis and/or treatment (theranostics) of diseases in humans and animals. In some aspects, a nanostructure carrier can be synthesized in the form of a nanobowl, which may include an actuatable capping particle that can be opened (and in some implementations, closed) on demand. In some aspects, a nanostructure carrier can be synthesized in the form of a hollow porous nanoparticle with a functionalized interior and/or exterior to attach payload substances and substances for magnetically guided delivery and controlled release of substance payloads.

Disclosed herein is a method for treating a cancer, the method includes following operations. A pharmaceutical composition is administered to a subject in need. The pharmaceutical composition includes a medium and a plurality of cisplatin-loaded microbubbles dispersed in the medium. Each cisplatin-loaded microbubble includes a shell portion and a core portion. The shell portion includes a plurality of albumin molecules and a plurality of first cisplatin molecules covalently bonding to the albumin molecules. The core portion is surrounded by the shell portion, wherein the core portion includes a mixture of inert gas and a plurality of second cisplatin molecules. Ultrasound energy is then applied to a tumor of the subject to break the cisplatin-loaded microbubbles.

The present disclosure relates to compositions and methods for restoring endothelial glycocalyx. Exemplary compositions include nanoparticle compositions of preassembled glycocalyx.

Non-viral delivery platforms are provided for facilitating transport of molecules across cell membranes. In some forms, DNA nanoshells capable of transporting cargo molecules are formed, and may be formed in order to surround a variety of materials for a variety of purposes.

A method of macular disease treatment (500) may include introducing nanocapsules into a body of a patient (502). The nanocapsules may be introduced such that the nanocapsules circulate through at least a portion of a body of the patient. A therapeutic substance and a colorant may be encapsulated into the nanocapsules. After a portion of the nanocapsules enters choroidal neovessels of an eye of the patient, the method may include emitting a pulsed laser radiation through a pupil of the eye (504). Additionally, after a portion of the nanocapsules enters choroidal neovessels of an eye of the patient, the method may include heating the portion of the nanocapsules present in the eye (506) such that at least a portion of the nanocapsules transfer phase and release the therapeutic substance.

A method of manufacturing a suspension of gas-filled microvesicles by reconstituting a freeze-dried product and a suspension obtained according to said method, where the freeze-dried product has been subjected to a thermal treatment.

Disclosed herein are embodiments of a functionalized microbubble designed for treating and/or preventing vascular obstructions, including microvascular obstructions. The functionalized microbubble embodiments comprise a microbubble that can be activated upon exposure to ultrasound and further that has a lipid-based shell that is attached to an exteriorly-attached therapeutically active agent, such as a thrombolytic agent. Also disclosed herein are embodiments of a method for making and using the functionalized microbubble embodiments.

Disclosed is use of a composition for preventing or treating an inflammatory disease and a metabolic disease. The composition includes hyaluronic acid nanoparticles formed in such a way that 5-cholanic acid or polycaprolactone binds to a hydrophobic moiety of hyaluronic acid through self-assembly in an aqueous solution state.

A pharmaceutical composition includes a plurality of metal nanoparticles and at least one therapeutic agent. Each of the metal nanoparticles includes a core and a stabilizing agent coated on a surface of the core. The at least one therapeutic agent is attached to the stabilizing agent of the metal nanoparticles. Each of the therapeutic agent is an amphiphilic compound and has at least one hydrophobic chain interacting with the stabilizing agent. The pharmaceutical composition may further include a polymer shell encapsulating the metal nanoparticles and the therapeutic agent for enabling controlled release of the therapeutic agent. The pharmaceutical compositions are bifunctional and may be used for diagnosing and treating cancer. Methods for using the pharmaceutical compositions in conjunction with radiation therapy to diagnose and treat cancer are also provided.

Methods and compositions for treating a patient for a condition characterized by an excess blood concentration of dissolved gas in at least one targeted region of the patient are provided. The method comprises administering a composition comprising a perfluorocarbon droplet emulsion into the blood of the patient; insonifying the at least one target region sufficient to achieve formation of microbubbles by droplet vaporization of at least a portion of the perfluorocarbon droplets present in the blood; whereby a concentration gradient favoring movement of gas molecules from the blood into the microbubbles is established for a time frame.