An electromagnetic radiation activated device comprises a property changing material and at least one functionalized fullerene that upon irradiation of the functionalized fullerenes with electromagnetic radiation of one or more frequencies a thermally activated chemical or physical transformation occurs in the property changing material. The thermal activated transformation of the property changing material is triggered by the heating or combustion of the functionalized fullerenes upon their irradiation. The device can include a chemical agent that is embedded in the property changing material and is released when the material is heated by the functionalized fullerenes upon irradiation.

A self-cleaning cannula for placement in a patient, including an elongated tube portion having an inner surface and an oppositely disposed outer surface, a first end fluidically connectable to a fluid source outside the patient and a second, oppositely disposed end for fluidically communicating with the patient, and a plurality of magnetic nanoparticles operationally connected to at least a portion of the cannula. The metallic nanoparticles may be energized by an applied oscillating magnetic field to heat the cannula.

A self-cleaning cannula for placement in a patient, including an elongated tube portion having an inner surface and an oppositely disposed outer surface, a first end fluidically connectable to a fluid source outside the patient and a second, oppositely disposed end for fluidically communicating with the patient, and a plurality of magnetic nanoparticles operationally connected to at least a portion of the cannula. The metallic nanoparticles may be energized by an applied oscillating magnetic field to heat the cannula.

A self-cleaning cannula for placement in a patient, including an elongated tube portion having an inner surface and an oppositely disposed outer surface, a first end fluidically connectable to a fluid source outside the patient and a second, oppositely disposed end for fluidically communicating with the patient, and a plurality of magnetic nanoparticles operationally connected to at least a portion of the cannula. The metallic nanoparticles may be energized by an applied oscillating magnetic field to heat the cannula.

Methods and catheters suitable for removing or reducing the formation of cellular occlusion associated the catheters. The catheters include a surface coated or infused with magnetic nanoparticles. Once the catheter is implanted in a subject, the nanoparticles induce localized hyperthermia around the catheter in response to a magnetic field.

Devices and methods relate to inducing or promoting hemostasis. The hemostasis device may include a support layer having a first surface and an opposing second surface. The device may include a layer, the layer disposed on the first surface. The layer may include a target surface configured to contact a target site. The layer may include a monolayer of about 100% graphene or may include laser-reduced graphene oxide. The device may include a sensor configured to measure a level of hemostasis of the target site. The methods relate to a method of manufacturing a hemostatic device including a monolayer of graphene or a layer of laser-reduced graphene oxide.

A self-cleaning cannula for placement in a patient, including an elongated tube portion having an inner surface and an oppositely disposed outer surface, a first end fluidically connectable to a fluid source outside the patient and a second, oppositely disposed end for fluidically communicating with the patient, and a plurality of magnetic nanoparticles operationally connected to at least a portion of the cannula. The metallic nanoparticles may be energized by an applied oscillating magnetic field to heat the cannula.