A shockwave therapy system integrating sensory deprivation and artificial intelligence-controlled treatment delivery is disclosed. The system may comprise a sensory deprivation chamber containing a body of water in which a patient floats while receiving shock wave therapy. The therapy may be delivered through multiple robotic arms that may be controlled by an AI system which may optimize treatment parameters in real-time. The system may incorporate an Infinitus Omni Remote Sensor System mounted above the patient that may monitor vital signs through radar-based monitoring, infrared thermometry, and remote pulse oximetry. The monitoring data may be displayed to medical practitioners and may be integrated into the AI's treatment optimization protocols. This integrated approach may provide a method for delivering shock wave therapy in a controlled, floating environment while maintaining continuous patient monitoring and automated treatment optimization.

The disclosure describes a system and a method for applying a gradient of external compressive forces on the body of a person, in a manner analogous to how water exerts hydrostatic forces on the body of a person immersed in water. According to an embodiment, the system may be a chair or a suit and is applicable for effecting physiological changes in the body such as increased diuresis and/or amniotic fluid levels, preeclampsia treatment in pregnant women, reduced hypertension, shift in fluids from interstitial space into intravascular compartment, increased venous return from lower extremities, reduced sympathetic tone and total peripheral resistance, reduced work load on the heart, reduced motion sickness, and the like.

This disclosure relates generally to systems, devices, and methods of use thereof regarding headrests for selectively removable spa seatbacks. In some embodiments, headrests of the present disclosure include a pillow and a manifold to (a) receive the pillow and (b) selectively engage the selectively removable spa seatback. In some embodiments, headrests of the present disclosure include a pillow and a manifold, where the manifold includes a platform to receive the pillow, a body for engaging with the selectively removable spa seatback, and a constraining plate to restrict a movement of a portion of the body.

A bath massage chair includes a pillow, a back support configured to support a torso of the user when the user is seated in the bath massage chair, and a seat coupled to the lower portion of the back support. The pillow includes a pillow massage system and a pillow heating element configured to heat the pillow. The back support includes an upper portion coupled to the pillow and a lower portion opposite the upper portion, a back massage system configured to massage the torso of the user, and a back heating element configured to heat the back support. The seat is configured to support a lower body of the user when the user is seated in the bath massage chair. The pillow massage system, pillow heating element, back massage system, and back heating element are operably coupled to a controller.

A spa jet body that provides venturi in a crosswise and tangential orientation to the exit port of water/air mixture which provides for the elimination of moving parts inside of the jet body to create turbulence when in a perpendicular orientation and preserves precious space behind a vertical spa wall or a spa foot well. The venturi enters the inner circumference of the jet body turbulence chamber in a tangential and crosswise orientation, creating turbulence therein with the water/air mixture exiting out the massage head in a pulsating manner, the massage head being a face plate with exit apertures, some of them being specially designed for the footwell. The face plate connects to the jet body through a nut which is secured with screws that pass through the face plate onto the open perimeter top of the jet body.