A handheld device for applying mechanical vibration to a body portion of an individual to treat a condition of the individual, includes: a housing; a cantilever beam having a first portion accommodated in the housing, and a second portion that is moveable relative to the housing, wherein the second portion is configured to apply the mechanical vibration to the body portion; and a motor in the housing, the motor configured to oscillate the second portion of the cantilever beam at an oscillation frequency.

A percussive therapy system includes a percussive therapy device that includes a housing, an electrical source, a motor positioned in the housing, a switch for activating the motor, a push rod assembly operatively connected to the motor and configured to reciprocate in response to activation of the motor, and an attachment configured to be operatively connected to a distal end of the push rod assembly of the percussive massage device and to provide at least one therapeutic effect to a user. The attachment may include at least one of an actuator configured to provide the at least one therapeutic effect to the user and a sensor configured to obtain at least one of biometric data of the user and information regarding operation of the percussive therapy device.

A massage head unit, a vibration assembly and a smart wearable device, including: a soft rubber base plate, a plurality of vibrating members, a plurality of soft rubber massage heads, and a plurality of soft rubber pleated bodies capable of stretching and deforming in a axial direction of each massage head; the base plate, the pleat bodies and the massage heads are integrally molded by injection molding, the base plate is provided with a plurality of through holes penetrating therethrough, and the through holes, the pleated bodies and the massage heads are in one-to-one correspondence, each massage head is provided with a mounting cavity mounted with at least one vibrating member, each pleated body is connected to a bottom of the massage head and an edge of the through hole, such that each of the massage heads is floating and supported on the edge of the through hole.

In a small massaging tool, numbness in fingers, strangeness, fatigue, and other discomfort, which are caused due to vibration of a grip part that is caused by vibration of a vibration motor, are eliminated to maintain comfortable use and vibration noise is reduced. The massaging tool includes a head unit 30 including vibrating parts 50 and 52 and a vibration motor 40 that vibrates the vibrating parts, a battery that is a power source of the vibration motor, and a body 10 having the vibration motor and the battery accommodated therein and having the grip part, wherein the head unit is supported in a floating state with respect to the body by a cushioning member made of gel-like resin and fixed to the body.

Disclosed are systems, devices, methods and computer-readable medium products that implement a vibrational event by a wearable drug delivery device. The wearable drug delivery device includes vibrational actuators that vibrate in response to a control signal from a controller. The controller may be controlled by an external device that issues command signals with instructions related to settings of the vibrational event. The vibrational event settings may be modified based on signals received from sensors on the wearable drug delivery device. The vibrational events may be implemented as an element of a site maintenance plan that alleviates the degeneration of tissue at one or more body attachment sites of the wearable drug delivery device.

A cooling attachment module for use with a vibration therapy device that includes a housing and/or heat sink member that includes inner and outer walls and defines a central opening axially therethrough. A cooling recess is defined in an upper surface and a connection recess is defined in a lower surface of the heat sink member. A cover member is secured over the cooling recess. A controllable temperature element is positioned on an upper surface of the heat sink member. A spreader member is positioned on an upper surface of the controllable temperature element. An upper surface of the spreader member is positioned above an upper surface of the cover member to contact a user's body part. The controllable temperature element is configured to transfer thermal energy to a lower surface of the spreader member. A base portion that includes an electrical connector is secured under the electrical recess.

A device is described which can measure changes in cerebral spinal fluid (CSF) pressure as a function of body tilt, with an added feature of delivering particular vibrations to a body. By measuring changes in CSF pressure with tilt, one can determine, among other things, a body's ability to regulate CSF pressure. In addition, when coupled with the delivery of therapeutic vibration to a body, an improvement in CSF pressure regulation and patency can be established. The device may include at least two motors in a housing with unbalanced masses coupled to their axles, such that vibration of the masses causes the two motors and housing to vibrate at a beat frequency 80. The motors and housing may be coupled to the body via a platform which places the motors and housings at or near a resonant structure in the body, creating a coupled oscillation between the platform and the body. The vibration may be based on the input signal, such that the system applies the vibration based on the input signal to the user, wherein the signal may be an audio or video signal. The system may be configured to measure and manipulate the flow of cerebral spinal fluid.

Methods and devices that improve focus, concentration, learning capacity, visual memory, new learning, sustained attention, cognition and/or interoception in a human using mechanical affective touch therapy are provided. In one embodiment, the method comprises delivering to a human body transcutaneous mechanical vibrations having a frequency of less than 20 Hz for at least 10 minutes, at least 2 times per day, for a period of at least 4 weeks, thereby providing the human with transcutaneous mechanical stimulation that improves focus, concentration, learning capacity, visual memory, new learning, sustained attention, cognition and interoception in that human.

A harmonic vibration fitness machine includes a base, a platform, a movable plate, a first drive unit and a second drive unit. The first drive unit uses a first motor to drive two first linkages through a first transmission shaft and a reduction gear set, so that the first linkages drive a platform to move up and down. The second drive unit uses a second motor to drive to second linkages through a second transmission shaft and a reduction gear set, so that the second linkages drive the movable plate to move up and down. The movable plate will be linked with the first linkages during the operation process, so that the up and down movement of the platform can be multiplied. So, the harmonic vibration fitness machine can achieve the effect of single platform and double amplitude action.

A lung gas exchange device includes a front housing, at least one strap configured to affix the front housing to an anterior neck of a user, a vibration device positioned within the front housing, a wear plate configured to transfer vibration from the vibration device to the anterior neck of the user, a power source configured to provide power to the vibration device, a power control mechanism configured to allow a user to turn on and off the vibration device; and a central processing unit board connected to the power control mechanism, the power source, and the vibration device.