Abstract: A location monitoring system tracks a location of a user within a healthcare facility. When the user is detected in a patient room an electronic controller activates a voice command database having a plurality of voice commands specific to the user. A microphone located in the patient room receives one of the plurality of voice commands. The electronic controller transmits the one of the plurality of voice commands to a remote device positioned outside of the patient room.

Abstract: A location monitoring system tracks a location of a user within a healthcare facility. When the user is detected in a patient room an electronic controller activates a voice command database having a plurality of voice commands specific to the user. A microphone located in the patient room receives one of the plurality of voice commands. The electronic controller transmits the one of the plurality of voice commands to a remote device positioned outside of the patient room.

Abstract: A location monitoring system tracks a location of a user within a healthcare facility. When the user is detected in a patient room an electronic controller activates a voice command database having a plurality of voice commands specific to the user. A microphone located in the patient room receives one of the plurality of voice commands. The electronic controller transmits the one of the plurality of voice commands to a remote device positioned outside of the patient room.

Abstract: Devices, systems, and methods for blockchain data management for interaction of medical devices include distributed ledger of medical device information. Medical devices can form nodes of a medical device network for maintaining a device level interaction ledger. Medical devices can communicate with a network to manage access to the medical device interaction data.

Abstract: A location monitoring system tracks a location of a user within a healthcare facility. When the user is detected in a patient room an electronic controller activates a voice command database having a plurality of voice commands specific to the user. A microphone located in the patient room receives one of the plurality of voice commands. The electronic controller transmits the one of the plurality of voice commands to a remote device positioned outside of the patient room.

Abstract: A system is provided that monitors information from locating equipment and nurse call equipment and that provides notifications to caregivers so that patient care processes are maintained or modified to ensure high levels of patient satisfaction or patient safety.

Abstract: A system is provided that monitors information from locating equipment and nurse call equipment and that provides notifications to caregivers so that patient care processes are maintained or modified to ensure high levels of patient satisfaction or patient safety.

Abstract: Apparatus and methods for noninvasively measuring blood density and hematocrit in a human subject can include an appliance for applying pressure around a segment of a subject's limb or appendage that includes a pressure sensing means and encloses an array of impedance sensing devices applied to the subject's skin for independent fluid volume measurements. While applying pressure to the limb segment by the pressure appliance, measurements of blood pressure, blood pulse wave velocity, and limb segment impedance are recorded. The measurements are subsequently processed to yield changes of arterial blood volume during pulse wave passage. Then pressure, wave velocity, and derived volume data are combined to yield the density of the blood. Blood density is converted to hematocrit by means of a linear relationship between the two. Independent of the blood hematocrit, such apparatus and means may also be used to measure the density of enclosed fluid in other pulsed flow non-rigid wall vessel systems.

Abstract: Apparatus and methods for noninvasively measuring blood density and hematocrit in a human subject can include an appliance for applying pressure around a segment of a subject's limb or appendage that includes a pressure sensing means and encloses an array of impedance sensing devices applied to the subject's skin for independent fluid volume measurements. While applying pressure to the limb segment by the pressure appliance, measurements of blood pressure, blood pulse wave velocity, and limb segment impedance are recorded. The measurements are subsequently processed to yield changes of arterial blood volume during pulse wave passage. Then pressure, wave velocity, and derived volume data are combined to yield the density of the blood. Blood density is converted to hematocrit by means of a linear relationship between the two. Independent of the blood hematocrit, such apparatus and means may also be used to measure the density of enclosed fluid in other pulsed flow non-rigid wall vessel systems.

Abstract: The present invention provides means and methods for noninvasively identifying the blood pressure characteristics in each of the seven types of vessels in the circulatory system, including the central venous pressure (CVP) through a single monitoring system using fluid depletion plethysmography. Known pressure is applied to a body region in increasing amounts to force blood volume from the body region in step-wise fashion through each vessel type. Blood volume depletion for each vessel type is measured by the increasing electrical impedance of the body part during depletion and is plotted against the increasing pressure data. The resulting series of slope changes within the plotted curve reveals the blood pressure for each vessel type. The data obtained may further be used to determine vessel wall compliance/tension as well as standard measurements such as pulse and large artery systolic and diastolic pressure.

Abstract: The present invention provides means and methods for noninvasively identifying the blood pressure characteristics in each of the seven types of vessels in the circulatory system, including the central venous pressure (CVP) through a single monitoring system using fluid depletion plethysmography. Known pressure is applied to a body region in increasing amounts to force blood volume from the body region in step-wise fashion through each vessel type. Blood volume depletion for each vessel type is measured by the increasing electrical impedance of the body part during depletion and is plotted against the increasing pressure data. The resulting series of slope changes within the plotted curve reveals the blood pressure for each vessel type. The data obtained may further be used to determine vessel wall compliance/tension as well as standard measurements such as pulse and large artery systolic and diastolic pressure.