Devices and methods for assisting breathing in a subject are described. In one embodiment, a device includes a splint that can be used to apply negative distending pressure, i.e., outward pull, to one or both of the chest walls and/or the abdomen of a subject. The splint may include an air bladder that can be attached to the skin of the subject's chest and/or abdomen. When the air bladder is inflated, negative distending pressure is applied to the subject's chest and/or abdomen, thereby assisting or promoting respiration. The inflated air bladder may also apply a compressive force on the chest to facilitate expiration, and the removal of secretions in the airways.

In an embodiment, a compression garment can include one or more of a flex frame, a shape memory material, a backing, and a control module. In some variations, the flex frame can include a set of support regions, a set of cutout regions, a set of bridges, one or more terminals, and one or more rotation points. In some variations, the compression garment 100 can further include a fabric sleeve, one or more fasteners, a power module, and/or any other suitable component. The compression garment functions as a compression device (e.g., to improve circulation, enhance muscle recovery, etc.), and can additionally or alternatively function as a passive compression device, a heating and/or cooling device, or perform any other suitable functionality.

The Conformal Vest Ventilator (CVV) is a vest-like mechanism to cause or aid breathing in humans The Conformal Vest Ventilator consists of a series of expanding and contracting tubes that fit around the torso, similar to clothing, and which change shape in a manner that expands the thoracic cavity to create negative pressure ventilation in the lungs, similar to the natural ventilation created by the diaphragm muscle and the expanding rib cage. The CVV creates a breathing support system that is less intrusive than existing methods, and can improve the lives of people with COPD or paralyzed diaphragm muscles and is useful in other medical conditions, including sleep apnea, critical care, spinal cord injuries, and athletic training or physical therapy when the primary goal is to increase lung capacity.

A system for providing treatment adapted to clear lung airways, the system including at least one pressure applicator adapted, when activated, to apply pressure at at least one specific location on a torso of a patient, and, when deactivated, to release the pressure, a sensor for sensing a signal associated with the patient, and, a controller, in communication with the sensor, adapted to analyze the signal and to control activation and deactivation of the at least one pressure applicator based, at least in part, on analyzing the signal. Related apparatus and methods are also described.

A connector for an inflatable garment that detects a valid connection with a pump.

A method for cardiopulmonary resuscitation (CPR) includes supplying an inflation gas at an operative pressure to an inflation actuated soft gripper device to change form from an undeployed state to a deployed grip state that accommodates and grips a human torso. The inflation actuated soft gripper device includes a first inflatable gripper arm having a first distal end and a second inflatable gripper arm having a second distal end. The first distal end and the second distal end approach one another from the undeployed state to the deployed grip state. The first and second distal ends are spaced apart from one another further in the undeployed state than in the deployed grip state. An actuator power and a CPR control signal are delivered to a CPR pressure application device to cyclically extend and retract a pressure applicator along an axis in alignment with a sternum of the human torso.

The invention disclosed here relates in general to the field of medical devices. In particular, to devices and methods for improving the clinical outcome of patients suffering from cardiac dysrhythmias without cardiac arrest. This method and/or device integrates mechanical, pneumatic, acoustic and/or electrophysiologic capabilities with electrical countershock or pacing capabilities such that the probability of successful cardioversion or pacing is increased. The sequence, forces, and electrical properties of the subsystems can be computer controlled and adjusted in response to biomarker inputs.

A system and method for integrating and synchronizing an automated mechanical cardiopulmonary resuscitation (CPR) device with components of cardiac catheterization laboratories so as to enhance the efficacy of each intervention. Synchronization can include image gating so that a monitor shows real time images during relaxation of the CPR, and a static image during compression of the CPR.

A device and method for loosening mucous secretions from a subjects lungs including a vest-like garment having enclosures thereon, the enclosures containing one or more sonic transducers, the output face of which is arranged to face the subject's body, the sonic transducers configured to repeatedly emit sonic bursts having a duration of about 10 to about 50 milliseconds at one or more frequencies ranging from 100 Hz-400 Hz, at a rate of about one to about four bursts per second.

A medical vast and using method thereof. The medical vest has a clothe capable of surrounding the chest of a user's body, one or more vibration devices located in the clothe respectively and a motion sensor located in the clothe. Hence, when a user wears the medical vest and/or when the user actives one or more vibration devices to apply a net vibration force to the users' chest, the motion sensor may detect the user's real posture and/or both the vibration intensity and/or the vibration frequency of the vibration force applied to the user's chest. Accordingly, the user may adjust the vibration intensity and/or the vibration frequency of one or more vibration devices, also may adjust how the clothe is worn on the user's chest.