A vibrating glass massager includes a glass vibration head having a base end, a free end, and a wall defining a hollow interior compartment that is closed at the vibration head free end and open at the vibration head base end. A vibration motor assembly is disposed in the vibration head interior compartment. A resilient vibration-transmitting interface is disposed between the vibration motor assembly and the vibration head wall. A non-glass base includes a base housing. The base housing and the vibration head base end are joined in interlocking relationship at a head-base connection interface. A power source and a control circuit are disposed in the base housing. The control circuit is electrically connected to the power source and to the vibration motor assembly. The glass vibration head is operable to deliver vibrations received from the vibration motor assembly via the vibration transmitting interface.

A method for stimulating contraction of a target muscle, the method including: locating a first neuromuscular junction of a target muscle by visualization or palpation, delivering a first stimulus to the first neuromuscular junction, locating a second neuromuscular junction of the target muscle by visualization or palpation, and delivering a second stimulus to the second neuromuscular junction. The first and second stimuli are effective to stimulate contraction of the target muscle. Further, contraction of the target muscle is effective to result in a measurable increase of at least one of: output force of the target muscle or range of motion of a body part associated with extension or contraction of the target muscle.

A method for stimulating contraction of a target muscle, the method including: locating a first neuromuscular junction of a target muscle by visualization or palpation, delivering a first stimulus to the first neuromuscular junction, locating a second neuromuscular junction of the target muscle by visualization or palpation, and delivering a second stimulus to the second neuromuscular junction. The first and second stimuli are effective to stimulate contraction of the target muscle. Further, contraction of the target muscle is effective to result in a measurable increase of at least one of: output force of the target muscle or range of motion of a body part associated with extension or contraction of the target muscle.

In an embodiment a system for facilitating a subject's functional development includes sensing devices configured for sensing mind state signals; sensing devices configured for sensing body state signals; and a set of processing resources configured for generating a mind state indicator/measure, a body state indicator/measure, and a mind-body synergy indicator/measure that corresponds to an expected extent to which each of the subject's mind state and the subject's body state are cooperatively or synergistically aligned with respect to facilitating the subject's functional development. In an embodiment, the system can be configured for concurrently presenting a set of activities involving a model body part; engaging the subject in attempted imitation of the set of activities by way of attempted movement of a subject body part that is a mirror image of the model body part; presenting an indication of an expected extent to which each of the subject's mind state and body state are cooperative with respect to subject performance of the set of activities; and presenting an indication of an extent of subject relaxation. An associated multiple (e.g., up to 12) degree of freedom robotic orthosis can include a set of appendage motion modules configured for engaging with a portion of a subject appendage; a set of mechanical power interface modules coupled to the set of appendage motion modules and configured for facilitating movement of appendage motion modules within the set of appendage motion modules; and a set of flexible drive shafts couplable to the set of mechanical power interface modules.

In an embodiment a system for facilitating a subject's functional development includes sensing devices configured for sensing mind state signals; sensing devices configured for sensing body state signals; and a set of processing resources configured for generating a mind state indicator/measure, a body state indicator/measure, and a mind-body synergy indicator/measure that corresponds to an expected extent to which each of the subject's mind state and the subject's body state are cooperatively or synergistically aligned with respect to facilitating the subject's functional development. In an embodiment, the system can be configured for concurrently presenting a set of activities involving a model body part; engaging the subject in attempted imitation of the set of activities by way of attempted movement of a subject body part that is a mirror image of the model body part; presenting an indication of an expected extent to which each of the subject's mind state and body state are cooperative with respect to subject performance of the set of activities; and presenting an indication of an extent of subject relaxation. An associated multiple (e.g., up to 12) degree of freedom robotic orthosis can include a set of appendage motion modules configured for engaging with a portion of a subject appendage; a set of mechanical power interface modules coupled to the set of appendage motion modules and configured for facilitating movement of appendage motion modules within the set of appendage motion modules; and a set of flexible drive shafts couplable to the set of mechanical power interface modules.

A method for stimulating contraction of a target muscle, the method including: locating a first neuromuscular junction of a target muscle by visualization or palpation, delivering a first stimulus to the first neuromuscular junction, locating a second neuromuscular junction of the target muscle by visualization or palpation, and delivering a second stimulus to the second neuromuscular junction. The first and second stimuli are effective to stimulate contraction of the target muscle. Further, contraction of the target muscle is effective to result in a measurable increase of at least one of: output force of the target muscle or range of motion of a body part associated with extension or contraction of the target muscle.

A method for stimulating contraction of a target muscle, the method including: locating a first neuromuscular junction of a target muscle by visualization or palpation, delivering a first stimulus to the first neuromuscular junction, locating a second neuromuscular junction of the target muscle by visualization or palpation, and delivering a second stimulus to the second neuromuscular junction. The first and second stimuli are effective to stimulate contraction of the target muscle. Further, contraction of the target muscle is effective to result in a measurable increase of at least one of: output force of the target muscle or range of motion of a body part associated with extension or contraction of the target muscle.

A method and device for reducing the damaging effects of radiant energy, blast, or concussive events includes applying pressure to at least one jugular vein to reduce the egress of blood from the cranial cavity during or before the incidence of the imparting event. Reducing blood outflow from the cranial cavity increases intracranial volume and/or pressure of the cerebrospinal fluid to reduce the risk of traumatic brain injury and injuries to the spinal column. Reducing blood outflow further increases the intracranial pressure and volume, and thereby increases the pressure and volume of the cochlear fluid, the vitreous humor and the cerebrospinal fluid to thereby reduce the risk of injury to the inner ear, internal structure of the eye and of the spinal column. In addition, increasing intracranial pressure and volume reduces the likelihood of brain injury and any associated loss of olfactory function.

A method and device for reducing the damaging effects of radiant energy, blast, or concussive events includes applying pressure to at least one jugular vein to reduce the egress of blood from the cranial cavity during or before the incidence of the imparting event. Reducing blood outflow from the cranial cavity increases intracranial volume and/or pressure of the cerebrospinal fluid to reduce the risk of traumatic brain injury and injuries to the spinal column. Reducing blood outflow further increases the intracranial pressure and volume, and thereby increases the pressure and volume of the cochlear fluid, the vitreous humor and the cerebrospinal fluid to thereby reduce the risk of injury to the inner ear, internal structure of the eye and of the spinal column. In addition, increasing intracranial pressure and volume reduces the likelihood of brain injury and any associated loss of olfactory function.

The present invention relates to the combination of both an instrument or tool meant for massage or instrument assisted soft tissue mobilization and electrotherapy. Current tools do not allow for simultaneous use of the two modalities. This tool is coated with an epoxy-based powder coat that is often used in electrical components. This provides insulation from the electricity that is being run through the tool to the patient. There is also a location for the insertion of a wire that will connect to the electrotherapy device. The use of the two together will allow for the practitioner to combine the benefits of both instrument assisted soft tissue mobilization and electrotherapy while saving time.