Abstract: In one aspect, a deployment station for portable emergency medical treatment and guidance apparatuses is provided. The deployment station can include a first storage section for holding at least one emergency medical treatment and guidance apparatus that includes a plurality of medical supplies; a second storage section for holding at least one defibrillator including electronic circuitry to administer electrotherapy; a housing containing the first storage section and the second storage section, the housing including: a readiness indicator for indicating a readiness of the at least one emergency medical treatment and guidance apparatus and the at least one defibrillator based on obtained readiness information; and at least one processor and memory mechanically coupled to the housing and communicatively coupled to the readiness indicator.

Abstract: A system is provided for integrating at least one portable computing device with a resuscitative medical device such as a defibrillator. The system may include a carrying case coupled to the resuscitative medical device. The carrying case may include a storage space for the at least one portable computing device and a wireless charging system for charging the at least one portable computing device. The system may be configured to enable secure data transfer between each of the devices, including data communication and data storage. A processor of the resuscitative medical device may be configured to activate the wireless charging system and charge the at least one portable computing device under certain circumstances. The processor may further be configured to prioritize or optimize charging and data transfer between the resuscitative medical device and each of multiple portable computing devices.

Abstract: A system is provided for integrating at least one portable computing device with a resuscitative medical device such as a defibrillator. The system may include a carrying case coupled to the resuscitative medical device. The carrying case may include a storage space for the at least one portable computing device and a wireless charging system for charging the at least one portable computing device. The system may be configured to enable secure data transfer between each of the devices, including data communication and data storage. A processor of the resuscitative medical device may be configured to activate the wireless charging system and charge the at least one portable computing device under certain circumstances. The processor may further be configured to prioritize or optimize charging and data transfer between the resuscitative medical device and each of multiple portable computing devices.

Abstract: A system for assisting a rescuer in providing cardiopulmonary resuscitation (CPR) chest compressions includes a motion sensor configured to generate motion sensor signals indicative of chest motion and a defibrillator. The defibrillator includes a processor and a display screen configured to provide CPR feedback and defibrillation information. The processor is configured to receive the motion sensor signals, analyze the motion sensor signals for features characteristic of a chest compression delivery type to distinguish between chest compression delivery types comprising manual compression, non-automated ACD, and automated ACD, and selectively provide the CPR feedback at the display screen based on an identification of the chest compression delivery type such that the CPR feedback includes a plurality of CPR parameters for the manual compression delivery type and remove at least portions of the CPR parameters from the display screen for the non-automated ACD and the automated ACD compression delivery types.

Abstract: A system for assisting a rescuer in providing resuscitative treatment to a victim is described. The system includes a motion sensor configured to generate motion sensor signals that are indicative of motion of the chest of the victim during chest compressions, an input device configured to receive user input indicative of a type of chest compressions, an output device, and a processor, a memory, and associated circuitry, the processor communicatively coupled to the motion sensor, the input device, and the output device and is configured to receive the motion sensor signals and the user input indicative of the type of chest compressions, determine chest compression feedback for the rescuer based on the motion sensor signals, and control the output device to selectively provide the chest compression feedback for the rescuer based at least in part on the type of chest compressions indicated by the user input.

Abstract: A medical device system for providing sensor data capture includes a medical device that may include one or more removably coupled sensor hubs and that includes a display to provide sensor data and at least one data interface (DI) port that may be a sensor-agnostic DI (SA-DI) port and a data transfer cable that may be compatible with the sensor-agnostic DI port and includes a first electromechanical connector configured to detachably couple to the SA-DI port and a second electromechanical connector configured to couple to the sensor and that includes a cable memory and processor configured to execute stored software to format sensor data according to a protocol of the SA-DI port, an authentication circuit, and a cable isolation device to limit patient leakage current flow from the medical device to the sensor and to electrically isolate the authentication circuit from the cable processor and the cable memory.

Abstract: A system is provided for integrating at least one portable computing device with a resuscitative medical device such as a defibrillator. The system may include a carrying case coupled to the resuscitative medical device. The carrying case may include a storage space for the at least one portable computing device and a wireless charging system for charging the at least one portable computing device. The system may be configured to enable secure data transfer between each of the devices, including data communication and data storage. A processor of the resuscitative medical device may be configured to activate the wireless charging system and charge the at least one portable computing device under certain circumstances. The processor may further be configured to prioritize or optimize charging and data transfer between the resuscitative medical device and each of multiple portable computing devices.

Abstract: A system for assisting a rescuer in providing resuscitative treatment to a victim is described. The system includes a motion sensor configured to generate motion sensor signals that are indicative of motion of the chest of the victim during chest compressions, an input device configured to receive user input indicative of a type of chest compressions, an output device, and a processor, a memory, and associated circuitry, the processor communicatively coupled to the motion sensor, the input device, and the output device and is configured to receive the motion sensor signals and the user input indicative of the type of chest compressions, determine chest compression feedback for the rescuer based on the motion sensor signals, and control the output device to selectively provide the chest compression feedback for the rescuer based at least in part on the type of chest compressions indicated by the user input.

Abstract: A carriage for a limb support includes a space for receiving a longitudinal member of a patient support apparatus, a plurality of rollers configured to engage the longitudinal member and a locking mechanism. The plurality of rollers is configured to maintain alignment of the carriage during movement of the carriage along the longitudinal member. The carriage also includes an elastomeric member that resists rotation to prevent unwanted motion of the carriage. The locking mechanism is configured to secure the carriage to the longitudinal member at any of an infinite number of positions along the length of the longitudinal member, the locking mechanism being lockable with a single action.

Abstract: A carriage for a limb support includes a space for receiving a longitudinal member of a patient support apparatus, a plurality of rollers configured to engage the longitudinal member and a locking mechanism. The plurality of rollers is configured to maintain alignment of the carriage during movement of the carriage along the longitudinal member. The carriage also includes an elastomeric member that resists rotation to prevent unwanted motion of the carriage. The locking mechanism is configured to secure the carriage to the longitudinal member at any of an infinite number of positions along the length of the longitudinal member, the locking mechanism being lockable with a single action.

Abstract: A carriage for a limb support includes a space for receiving a longitudinal member of a patient support apparatus, a plurality of rollers configured to engage the longitudinal member and a locking mechanism. The plurality of rollers is configured to maintain alignment of the carriage during movement of the carriage along the longitudinal member. The carriage also includes an elastomeric member that resists rotation to prevent unwanted motion of the carriage. The locking mechanism is configured to secure the carriage to the longitudinal member at any of an infinite number of positions along the length of the longitudinal member, the locking mechanism being lockable with a single action.

Abstract: A carriage for a limb support includes a space for receiving a longitudinal member of a patient support apparatus, a plurality of rollers configured to engage the longitudinal member and a locking mechanism. The plurality of rollers is configured to maintain alignment of the carriage during movement of the carriage along the longitudinal member. The carriage also includes an elastomeric member that resists rotation to prevent unwanted motion of the carriage. The locking mechanism is configured to secure the carriage to the longitudinal member at any of an infinite number of positions along the length of the longitudinal member, the locking mechanism being lockable with a single action.

Abstract: A surgical positioning aid includes a sheet of foldable material foldable between a flat position and a wrist support position. In the wrist support position, the sheet is folded to form a hump having sufficient strength to support a patient's wrist in a hyper-extended position during surgery. The sheet also includes a coupler situated at a first end region of the sheet. The coupler is operable to engage an opposite, second end region of the sheet and to hold the sheet in the wrist support position. Many other surgical positioning aid embodiments are also disclosed.