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.

An ultrasonic irradiation apparatus includes an ultrasonic resonator capable of generating ultrasound, a driving unit configured to drive the ultrasonic resonator, a case holding the ultrasonic resonator and the driving unit, an acoustic matching layer provided between the ultrasonic resonator and the case, and an acoustic diffusion layer made of an ultrasound diffusing material configured to diffuse high intensity ultrasound emitted from the ultrasonic resonator and convert the high intensity ultrasound into low intensity ultrasound with low intensity per unit area and radiate in a large area. The ultrasonic resonator is a piezoelectric resonator, the ultrasound diffusing material of the acoustic diffusion layer is made of a metal material of an acoustic impedance of at least 40, and the acoustic diffusion layer is provided in at least one of inside of the acoustic matching layer, inside of the case, and outside of the case.

Various embodiments, described herein, provide methods and systems for the treatment of plantar fascia. In some embodiments, a method of non-invasive treatment of plantar fascia can include the steps of identifying a damage location comprising a planter fascia; directing a conformal distribution of ultrasound energy to the plantar fascia at the damage location; creating a plurality of micro lesions in the plantar fascia at the damage location; initiating healing of a plurality of micro tears in the plantar fascia at the damage location; and sparing intervening tissue between the plantar fascia and a surface of a sole of a foot.

Various embodiments, described herein, provide methods and systems for the treatment of plantar fascia. In some embodiments, a method of non-invasive treatment of plantar fasciacan include the steps of identifying a damage location comprising a planter fascia; directing a conformal distribution of ultrasound energy to the plantar fascia at the damage location; creating a plurality of micro lesions in the plantar fascia at the damage location; initiating healing of a plurality of micro tears in the plantar fascia at the damage location; and sparing intervening tissue between the plantar fascia and a surface of a sole of a foot.

Systems and methods disclosed herein provide efficacious pain management therapies based on delivery of physical medicine(s) via computer-implemented systems. Patient information comprising patient pain symptoms, patient physiological measurements, patient demographics, and other information is received at a pain therapy device. The patient information is compared with pain analytics data compiled on a plurality of individuals to determine a personalized pain management therapy. The personalized pain management therapy is applied via a combination of thermoceuticals, electroceuticals, ultrasound, and several other forms of physical medicine. Sensors coupled to the pain therapy device measure changes in physiological data resulting from the pain management therapy. The personalized pain management therapy can be adjusted based on the changes in the physiological data and/or patient feedback. The patient information, information about the applied therapy, and therapy outcome information is added to the analytics database.

The invention provides a shape memory spacer fabric composite, being a spacer fabric coated with a shape memory polymer layer, wherein the spacer fabric comprises a first outer layer, a second outer layer and an intermediate spacing layer connecting the first outer layer and the second outer layer; the shape memory polymer layer is made from at least one block or random copolymer selected from the group consisting of the following: polyesters, polyurethanes, polyamides, polyols; the copolymer has at least one phase transition temperature in a range of 4080 C.

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.

An object delivery arrangement is disclosed for delivering objects into bone. The arrangement is configured for generating localized mechanical waves into a tissue, for performing localized deposition of the objects near bone, and for exposing the objects and the bone to said mechanical waves to obtain deposition of the objects into the bone.

Implantable bone fixations apparatus comprising a pair of plates (1 and 1) provided with holes (11, 12, 13) for receiving compression and/or locking screws and with longitudinal slots (15), characterized by a union element (3) disposed between the plates (1, 1) such as to bridge the bone parts that need to be united, the union element (3) comprising rods that cooperate with the longitudinal slots (15) of the plates (1, 1).