Provided is a smart contact lens for non-invasive drug delivery including a platform configured to be worn on an eye, a reservoir installed within the platform, and having a receiving part in which a drug is received, to provide the eye with the drug, an electrode for iontophoresis installed in the reservoir to make iontophoresis work, to provide the eye with the drug from the reservoir, and an activation chip electrically connected to the electrode for iontophoresis to activate iontophoresis.

Provided herein are methods of inducing an immune response against Severe Acute Respiratory Syndrome coronavirus 2 (SARS-CoV-2) in a subject in need thereof by administering an immunogenic composition to the subject, wherein the subject exhibits: an increase in antigen-specific cellular immune response as measured by Interferon-gamma (IFN-γ) Enzyme-linked Immunospot (ELISpot) assay relative to baseline; and/or an increase in neutralizing antibody response as measured by a pseudovirus neutralizing assay relative to baseline.

A method and system for noninvasively treating a neurodegenerative disorder, can involve determining characteristics indicative of physical attributes of a central nervous system, the characteristics including parameters for diminishing adverse impacts of a magnetothermal stimulation treatment for a neurodegenerative disorder with respect to the central nervous system, and applying as a part of the magnetothermal stimulation treatment and based on the characteristics of the physical attributes of the central nervous system, a magnetic field to the brain for a thermal stimulation of neuron cells within the brain.

An iontophoretic patch for transdermal delivery of biologically active agents includes at least two electrodes in contact with at least two hydrogel reservoirs. At least one of the hydrogel reservoirs carries at least one active agent and, in use of the iontophoretic patch, is disposed on a user's skin and delivers at least one active agent into the skin. The patch includes a control unit to generate a stimulation pattern having stimulation parameters delivered to stimuli locations on the skin. A stimulation unit generates a time sequence of pulses from the stimulation parameters generated by the control unit. The patch further includes a demultiplexing unit configured to perform independent spatio-temporal distribution of the electrical pulses in the time sequence of pulses to at least one electrode; at least one optical sensing system, for continuously measuring an amount of the active agent in the hydrogel reservoir; and a feedback unit.

A nerve in a mammal is optogenetically transduced, wherein the nerve is susceptible to stimulus by selective application of transdermal light, and a light source is applied to dermis of the mammal at or proximate to the optogenetically transduced nerve, to thereby stimulate the nerve. A wearable device for optogenetic motor control and sensation restoration of a mammal includes a wearable support, a power source at the wearable support, a controller at the wearable support and in electrical communication with a power source, and a transdermal light source coupled to the controller.

The present invention is a new controlled drug system that can be used for targeting non-invasive neuromodulation enabled by focused ultrasound gated release of one or more small molecule neuromodulatory agents.

Use of a suspension of gas-filled microbubbles comprising a fatty acids di-ester of phosphatidylcholine (PC), a pegylated phos-phatidylethanolamines (PE-PEG) and a fatty acid in a therapeutic method, wherein said suspension is administered as subsequent boluses.

The present invention provides novel compositions and methods for targeted delivery of therapeutics. In particular, the invention provides compositions comprising a plurality of carriers, such as microbubbles, wherein at least one active agent is associated or co-administered with the plurality of carriers for delivery to a target site, e.g., an organ, a tissue, or a tumor site, in a subject. The present invention also provides methods for treating a disease or condition, methods of targeted delivery of an active agent, e.g., to a target site, in a subject, using the carriers based compositions of the invention. The present invention further provides apparatus, devices and methods for preparing the compositions of the present invention.

Presented herein are techniques for localized release of systemically circulating therapeutic substances, which combine many of the advantages of systematic and localized administration, while eliminating many of the associated drawbacks. More specifically, in accordance with the techniques presented herein, an electro-responsive biomaterial is systemically administered to a recipient of an electrically-stimulating implantable medical device. The electro-responsive biomaterial comprises a therapeutic substance that is only activated (e.g., released) in the presence of an electromagnetic field generated by the electrically-stimulating implantable medical device.

Described herein are electrospun core-shell fibers that include (i) a central core that is electrically conductive having an exterior surface, wherein the core comprises a first polymer and an electroconductive material; (ii) a shell adjacent to the exterior surface of the core, the shell comprising a second polymer; and (iii) one or more bioactive agents in the shell. In one aspect, the fibers are electrospun fibers. Additionally, described herein are methods for making and using the core-shell fibers.