A handheld acoustic shock wave or pressure pulse applicator device has a body structure and an applicator head. The body structure has a proximal end and a distal end with a longitudinal axis extending between the ends. The applicator head is at the distal end. the head emits pressure pulses or shock waves at an inclined angle relative to the longitudinal axis of the body structure. The applicator head has a balloon or lens or membrane through which the emitted pressure pulses or shock waves pass. The lens or membrane is configured to be coupled directly or indirectly to an exposed soft tissue surface of a palate inside a patient's mouth to direct emitted pressure pulses or shock waves to the brain. The applicator device can be configured with the inclined obtuse angle fixed between 150 degrees and 90 degrees or can be adjustable between 180 degrees and 90 degrees.

A massage device for an arm of a vehicle occupant includes a hand resting region having at least one moveable hand massaging element. The massage device also includes at least one forearm resting region with at least one moveable forearm massaging element and two lateral forearm support regions each with at least one moveable forearm massaging element.

A massage device for an arm of a vehicle occupant includes a hand resting region having at least one moveable hand massaging element. The massage device also includes at least one forearm resting region with at least one moveable forearm massaging element and two lateral forearm support regions each with at least one moveable forearm massaging element.

A garment with prepositioned, definite sensory stimulating devices attached. These sensory stimulating devices include, but are not limited to, electrical stimulation, audio and physical stimulation such as localised force generation, compression, constriction, vibration, and surround sound. Predetermined and defined actuators allow the wearer to receive tissue, nerve and/or muscle stimulation and/or contraction so that the stimulation is precise as determined by its ability to conform to the scientific methodology of repeatability, reproducibility and reliability; this being due to consistency of actuator positioning in one or multiple locals on the human body. A personal surround sound can also be integrated to the garment to ensure the wearer is always in the optimal position relative the speakers. These actuators can be force generators within the garment for the wearer to feel impact or apparatus or electrodes included in the garment to locally constrict and increase pressure on the wearer.

A garment with prepositioned, definite sensory stimulating devices attached. These sensory stimulating devices include, but are not limited to, electrical stimulation, audio and physical stimulation such as localised force generation, compression, constriction, vibration, and surround sound. Predetermined and defined actuators allow the wearer to receive tissue, nerve and/or muscle stimulation and/or contraction so that the stimulation is precise as determined by its ability to conform to the scientific methodology of repeatability, reproducibility and reliability; this being due to consistency of actuator positioning in one or multiple locals on the human body. A personal surround sound can also be integrated to the garment to ensure the wearer is always in the optimal position relative the speakers. These actuators can be force generators within the garment for the wearer to feel impact or apparatus or electrodes included in the garment to locally constrict and increase pressure on the wearer.

Equipment for self-care of patients with chronic pain, through inducing, intensifying and maintaining their own frissons and where multisensory and multimodal stimuli are used to achieve it; musical, visual, aromatic and vibrotactile and cold are applied on the cutaneous surface of the spine. In addition, the method for using them through perceptual learning is presented. The equipment includes a computer and a computer system with a music and video player, lighting, presentation of aromas and a closed hydraulic circuit with a hydraulic actuator.

A therapeutic device for treating one or more conditions associated with a user's nasal cavities, sinuses, and/or ear canals includes a vibration generator having an acoustic device operable to provide a sound; a seal configured to cover a nose, but not a mouth, of the user to form an air-tight chamber around the nose of the user; the vibration generator disposed in a housing connected to the seal; and a stand extending from the housing and including a ball bearing and a seat on which the ball bearing may rest, the stand including a hollow member and an orifice, the orifice disposed in the seat. The vibration generator provides the sound directly to the nose of the user. A positive pressure is created in the air-tight chamber when the user exhales, the positive pressure generating a lift force to lift the ball bearing from the seat.

A therapeutic device for treating one or more conditions associated with a user's nasal cavities, sinuses, and/or ear canals includes a vibration generator having an acoustic device operable to provide a sound; a seal configured to cover a nose, but not a mouth, of the user to form an air-tight chamber around the nose of the user; the vibration generator disposed in a housing connected to the seal; and a stand extending from the housing and including a ball bearing and a seat on which the ball bearing may rest, the stand including a hollow member and an orifice, the orifice disposed in the seat. The vibration generator provides the sound directly to the nose of the user. A positive pressure is created in the air-tight chamber when the user exhales, the positive pressure generating a lift force to lift the ball bearing from the seat.

A treatment force application device preferably for use on biological tissue includes a proximal end having a weight and having a support for a practitioner; a distal end having a treatment interface configured for applying a therapeutic treatment including at least a treatment force; and a connection between the support and the treatment interface. The connection is lockably adjustable by the practitioner to establish a placement of the treatment interface relative to the support. The weight is sufficient to substantially prevent movement of the treatment interface relative to the support when the connection is locked. The support enables movement of the practitioner to provide a practitioner force, and the practitioner force is transferred from the support to the treatment interface through the connection. The support includes at least one flexible brace against which the practitioner can press to provide the practitioner force. The therapeutic treatment further includes at least one of heat, cold, moisture, vibration, pulsing, ultrasound, radiation, chemicals, and medicine. The treatment interface can be configured for obtaining biometric, treatment, physical, mechanical, force and environmental data related to use of the device.

A treatment force application device preferably for use on biological tissue includes a proximal end having a weight and having a support for a practitioner; a distal end having a treatment interface configured for applying a therapeutic treatment including at least a treatment force; and a connection between the support and the treatment interface. The connection is lockably adjustable by the practitioner to establish a placement of the treatment interface relative to the support. The weight is sufficient to substantially prevent movement of the treatment interface relative to the support when the connection is locked. The support enables movement of the practitioner to provide a practitioner force, and the practitioner force is transferred from the support to the treatment interface through the connection. The support includes at least one flexible brace against which the practitioner can press to provide the practitioner force. The therapeutic treatment further includes at least one of heat, cold, moisture, vibration, pulsing, ultrasound, radiation, chemicals, and medicine. The treatment interface can be configured for obtaining biometric, treatment, physical, mechanical, force and environmental data related to use of the device.