The present disclosure provides implants, sensor modules, networks, and methods configured to establish transcutaneous power and transcutaneous bidirectional data communication using ultrasound signals between two or more medical devices located on and within a body of a patient.

A medical device includes a treatment module configured to apply a treatment to a patient. The medical device includes an interface configured to operatively connect to a removable storage device storing authorization data that identifies a level of treatment authorization. The medical device includes a processing device configured to perform operations in response to receiving user input indicating a treatment should be initiated. The operations include determining whether the removable storage device is valid for use with the medical device. If the removable storage device is determined to be valid, the authorization data is accessed. The processing device determines whether the treatment is authorized based on the accessed authorization data. If the treatment is determined to be authorized, the treatment module is controlled to apply the treatment. If the treatment is determined to not be authorized, the treatment module is controlled such that the treatment is not applied.

The invention relates to a method for the non-invasive fragmentation of residual biomaterial after bone augmentation, and to a device specifically adapted for said method.

The present invention relates to an ultrasound apparatus for efficiently applying ultrasound waves over a treated area by mechanically moving the ultrasound transducer over an area larger than the Effective Radiating Area (ERA) comprising: (a) an ultrasound transducer, connected by wiring, for dispersing ultrasound waves; (b) an electric actuator for spinning a crank, wherein a shaft is eccentrically attached to said crank for rotatably whirling said transducer in circles.

A bone stimulator (30,40,50,610,810,910), a bone stimulation system (200,600,800, 900) and method for bone fracture healing of a broken bone (930,830,630,55) in a body, which can speed up the healing rate. Accordingly, ultrasound (214) is used by the present system to power up the implanted bone stimulator (30,40,50,610,810, 910) for generating a stimulating electric current passing through a broken area (931, 831,631,56) in the broken bone (930,830,630,55) for bone fracture healing.

The present disclosure provides implants, sensor modules, networks, and methods configured to establish transcutaneous power and transcutaneous bidirectional data communication using ultrasound signals between two or more medical devices located on and within a body of a patient.

The present invention relates to a device, system and a method for high pressure shockwave treatment of biological tissue having a large treatment zone and in particular to such a device, system and method in which a large biological treatment area in treated in a non-drug, non-surgical treatment protocol utilizing ballistic shockwave generating device.

A medical device includes a treatment module configured to apply a treatment to a patient. The medical device includes an interface configured to operatively connect to a removable storage device storing authorization data that identifies a level of treatment authorization. The medical device includes a processing device configured to perform operations in response to receiving user input indicating a treatment should be initiated. The operations include determining whether the removable storage device is valid for use with the medical device. If the removable storage device is determined to be valid, the authorization data is accessed. The processing device determines whether the treatment is authorized based on the accessed authorization data. If the treatment is determined to be authorized, the treatment module is controlled to apply the treatment. If the treatment is determined to not be authorized, the treatment module is controlled such that the treatment is not applied.

A method for cell stimulation by mechanical energy as well as a method for determining a subject specific set of treatment parameters for acoustic wave stimulation and a method for validating a set of treatment parameters for acoustic wave stimulation. The method for determining a subject specific set of treatment parameters includes generating subject specific data, which includes measuring a geometric property of a body portion, and determining a target field distribution in the body portion. The method for validating a set of treatment parameters for acoustic wave stimulation includes determining a target field distribution of an acoustic field in a body portion, receiving a related set of treatment parameters for at least one transducer, generating a subject specific 3D model of the body portion, and determining a difference between the target field distribution and a field distribution determined in the subject specific 3D model.

A method for ultrasound stimulation of musculo-skeletal tissue structures includes generating a plurality of acoustic spatial-temporal modes comprised of a sinusoidal-complex, wherein the sinusoidal-complex has a modulation envelope that enhances spatial-temporal measurement accuracy at a site of a multi-layered biological tissue structure, and a pulse repetition frequency and duty cycle that are osteogenic at the site of the multi-layered biological tissue structure, beam steering the acoustic spatial-temporal modes to the site of the multi-layered biological tissue structure to promote tissue healing, and producing bi-modal stress levels in the multi-layered biological tissue structure that are sufficient to generate bone fracture healing.