Abstract: A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a pump, a heat exchanger, and a controller that automatically pauses thermal treatment of the patient prior the patient reaching a target temperature. During the pause, the controller assesses a reaction of the patient and changes a temperature of the fluid only inside the thermal control unit if the patient is likely to reach the target temperature without further thermal treatment. However, if the patient is unlikely to reach the target temperature without further thermal treatment, the controller restarts the thermal treatment. The controller may pause thermal treatment again prior to reaching the target temperature and assess the patient's reaction. In some embodiments, the controller may selectively include and exclude a fluid reservoir in a circulation channel within the thermal control unit.

Abstract: A system and method for analyzing directory service environment attack path choke points for an enterprise may continuously collect data about the attack paths and provide alerts.

Abstract: In one aspect, a system (5) for use in providing an approximation or estimation of a characteristic (for example, a bulk density value) of a deposit subject to a drilling operation is disclosed. In one form, the system (5) comprises a processor module (25) arranged in operable association with a network of sensors (30) operable for measuring one or more parameters relating to the operation of the drilling assembly (10). The processor module (25) is configured operable for receiving data/information derived from the network of sensors (30), and processing the data/information so as to provide a representation of the incursion (eg. depth of penetration into the relevant deposit) achieved by way of the drilling assembly (10).

Abstract: A system and method for analyzing directory service environment attack path choke points for an enterprise may continuously collect data about the attack paths and provide alerts.

Abstract: A thermal pad for controlling a patient's temperature includes first and second chambers defined between interior and exterior layers. The first chamber circulates a temperature controlled fluid from a first inlet to a first outlet. The second chamber is in fluid communication with a port and a plurality of holes defined in the interior layer. Pressurized gas supplied to the second chamber is vented onto the patient to control the microclimate between the patient's skin and the thermal pad. An additional third chamber is provided in some embodiments that urges the thermal pad into contact with the patient when subjected to negative gauge pressure. In other embodiments, a negative gauge pressure chamber is allowed to partially inflate in order to urge the thermal pad into contact with the patient.

Abstract: A thermal control unit controls the temperature of a fluid delivered to one or more thermal transfer devices (e.g. thermal pads) in contact with a patient. The thermal control unit generates thermal data while being used to treat the patient and is adapted to receive thermal history data previously generated by a different thermal control unit in the treatment of that patient. Both the current and previous thermal data are displayable on the thermal control unit currently being used, thereby giving the caregiver a complete picture of the thermal history of the patient. The thermal control unit may also be adapted to transmit its thermal data, as well as the thermal history data previously received from the other thermal control unit, to still another thermal control unit. The thermal history data transfer may take place via a cable, wirelessly, by a portable flash drive, or by other means.

Abstract: A thermal control unit controls the temperature of a fluid delivered to one or more thermal transfer devices (e.g. thermal pads) in contact with a patient. The thermal control unit generates thermal data while being used to treat the patient and is adapted to receive thermal history data previously generated by a different thermal control unit in the treatment of that patient. Both the current and previous thermal data are displayable on the thermal control unit currently being used, thereby giving the caregiver a complete picture of the thermal history of the patient. The thermal control unit may also be adapted to transmit its thermal data, as well as the thermal history data previously received from the other thermal control unit, to still another thermal control unit. The thermal history data transfer may take place via a cable, wirelessly, by a portable flash drive, or by other means.

Abstract: A thermal control unit supplies temperature controlled fluid to one or more thermal pads used to control the temperature of a patient. The thermal control unit includes a fluid outlet, fluid inlet, heat exchanger, pump, and a controller. The controller receives first and second data from at least two different sources to determine if the patient is shivering or not. The two different sources may include a temperature sensor adapted to detect a temperature of the fluid, a temperature sensor adapted to detect a temperature of the patient, a tissue oxygenation sensor, a vibration/motion sensor, a thermal image sensor, an electromyograph, and/or other sensors. In some embodiments, the thermal control unit takes one or more automatic actions in response to detection of patient shivering.

Abstract: A thermal control unit for delivering temperature-controlled fluid to one or more patient pads that are in contact with a patient is disclosed. The thermal control unit includes a fluid circuit with an inlet and outlet, a heat exchanger, a pump, and a controller. A fluid quality monitor is included in some embodiments to monitor a cleanliness of the circulating fluid and issue an alert if the cleanliness falls below a threshold. A valve may be included that is controlled by the controller based upon a measurement of the cleanliness of the circulating fluid and/or the passage of a predetermined amount of time. A second valve may also be included in some embodiments that selectively diverts fluid to an additional filter. The additional filter is used to determine if a cleaning action taken with respect to the circulating fluid was effective or not.

Abstract: A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a pump, first and second cooling units, and a controller that selectively enables and disables at least one of the cooling units based on one more factors, such as the temperature of the fluid. Alternatively or additionally, a variable speed fan is included in one or both of the cooling units that blows air over the condenser and the controller selectively controls the fan speed based on factors such as the temperature of the circulating fluid. The thermal control unit may be modified to accept a cartridge having its own cooling unit. When so modified, the controller communicates with a controller inside of the cartridge and coordinates control of the cartridge cooling unit and the cooling unit inside the thermal control unit that is external to the cartridge.

Abstract: A thermal control unit supplies temperature controlled fluid to one or more thermal pads used to control the temperature of a patient. The thermal control unit includes a fluid outlet, fluid inlet, heat exchanger, pump, and a controller. The controller receives first and second data from at least two different sources to determine if the patient is shivering or not. The two different sources may include a temperature sensor adapted to detect a temperature of the fluid, a temperature sensor adapted to detect a temperature of the patient, a tissue oxygenation sensor, a vibration/motion sensor, a thermal image sensor, an electromyograph, and/or other sensors. In some embodiments, the thermal control unit takes one or more automatic actions in response to detection of patient shivering.

Abstract: Patient support apparatuses, such as beds, cots, stretchers, recliners, operating tables, and the like include wireless mesh network transceivers that enable them to communicate with each other, and other devices, via mesh networks and/or ad hoc networks. One or more additional wireless transceivers are included, such as WiFi transceivers that enable direct communication with a healthcare facility network, such as an Ethernet. The mesh network communication between patient support apparatuses and other devices is used for any one or more of: extending the communication range of the existing IT infrastructure, efficiently routing data to the healthcare facility network, determining location of the patient support apparatuses and devices, transporting patient data from one patient support to the next as the patient moves, and for other aspects.

Abstract: A thermal control unit supplies temperature controlled fluid to a patient to control the patients temperature. The thermal control unit includes a fluid outlet, fluid inlet, heat exchanger, pump, patient core temperature probe port, auxiliary sensor port, and controller. The controller receives patient core temperature readings from the patient temperature probe port and auxiliary sensor readings from the auxiliary sensor port. The controller may control a temperature of the circulating fluid in both a feedback manner using patient core temperature readings and a feedforward manner using readings from the auxiliary sensor. The auxiliary sensor may measure a characteristic of the patients tissue indicative of thermal resistance, and/or the auxiliary sensor may measure a temperature of the patients tissue at an intermediate depth. The controller may use the intermediate temperature to predict arrival at a target patient temperature. The auxiliary sensor may be an ultrasonic sensor, infrared sensor, or the like.

Abstract: A thermal control system for controlling a temperature of a fluid delivered to a patient is provided. The system includes a thermal control unit having a fluid inlet and outlet, a circulation channel, a pump, a heat exchanger, a fluid temperature sensor and a controller that controls the heat exchanger in order to automatically bring a patients temperature to a target temperature. In some embodiments, the control unit includes a user interface adapted to receive a non-temperature patient parameter (e.g. BMI) that the controller uses, along with patient core temperature readings, to control the heat exchanger. The controller may also or alternatively control the heat exchanger based on both core and peripheral patient temperature readings. An auxiliary thermal therapy device for controlling a temperature of the patients blood, air breathed by the patient, and/or other fluid, may also be controlled by the thermal control unit.

Abstract: Patient support apparatuses, such as beds, cots, stretchers, recliners, operating tables, and the like include wireless mesh network transceivers that enable them to communicate with each other, and other devices, via mesh networks and/or ad hoc networks. One or more additional wireless transceivers are included, such as WiFi transceivers that enable direct communication with a healthcare facility network, such as an Ethernet. The mesh network communication between patient support apparatuses and other devices is used for any one or more of: extending the communication range of the existing IT infrastructure, efficiently routing data to the healthcare facility network, determining location of the patient support apparatuses and devices, transporting patient data from one patient support to the next as the patient moves, and for other aspects.

Abstract: A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a fluid inlet for receiving the fluid back, a pump, a heat exchanger, a controller, a patient temperature port for receiving patient temperature readings, a memory, a user interface, and an auxiliary input. In some embodiments, the controller is adapted to display an indication on the display identifying a type of auxiliary sensor that the user should couple to the auxiliary input in order to carry out the thermal therapy session. The memory may contain a set of alarm conditions and the controller may be adapted to allow a user to customize the set of alarm conditions. The controller may also display a combined graph showing both patient temperature readings and auxiliary input readings with respect to time.

Abstract: A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a fluid inlet for receiving the fluid back, a pump, a heat exchanger, a controller for controlling the heat exchanger, a patient temperature port for receiving patient temperature readings, a memory, and a user interface that displays various data regarding thermal therapy sessions applied to patients using the thermal control unit. In some embodiments, past statistical data from previous thermal therapy sessions is stored in the memory and the controller displays a comparison of a current parameter of the current thermal therapy session to the past statistical data. The controller may also or alternatively automatically select a particular type of screen to display based on a type of user of the thermal control unit. The controller may also or alternatively generate after-session thermal therapy reports.

Abstract: Methods and systems for assessing the risk of a human female subject for developing breast cancer. In particular, the present disclosure relates to combining a first clinical risk assessment, a second clinical assessment based at least on breast density, and a genetic risk assessment, to obtain an improved risk analysis.

Abstract: A non-invasive sensor unit adapted to be coupled to a patient includes a pair of light emitters spaced apart a known distance, and a pair light detectors. The light detectors detect light emitted from the emitters and scattered by a patient. The unit determines one or more cardiovascular characteristics of the patient from the scattered light, such as the patient's pulse wave velocity; a saturation of peripheral oxygen (SpO2) level; a temperature; a respiration rate; a heart rate; and a blood pressure. The light emitters emit light that may have wavelengths between 600 and 1000 nanometers. The unit, in some embodiments, is integrated into a patch adapted to be secured to the skin of the patient. Readings from the unit may be transmitted to a separate device spaced from the unit, such as via Bluetooth, WiFi, or by other means.

Abstract: A patient handling device includes a deck for supporting a patient support surface, a controller, and two light sources, which are operable to output light of different colors. The controller is in communication with the light sources and operable to monitor the plurality of conditions and to generate a first unified indication by illuminating one of the lights when all the conditions remain in their desired state, and to generate a second indication by illuminating the other light when any of the conditions change from their desired state.