Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.

An integrated control system for controlling components of a setting of a healthcare environment, the integrated control system including one or more wireless computing devices; one or more displays; a plurality of components of the setting, wherein at least one component of the plurality of components is an ozone sterilization system, an integrated air and lighting plenum, a surgical lighting system, a pass-through logistics cabinet, or a floor sterilization robot; and a server. The server includes a connection for connecting to a remote healthcare environment information system, and a receiver and a transmitter for communicating data between the plurality of components of the setting, medical equipment connected to one of the plurality of components, the remote healthcare environment information system, the one or more wireless computing devices and the one or more displays.

Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.

Described herein are components, systems, and methods of use of an integrated sterilization system comprising a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components. An integrated operating room sterilization system will allow mitigation or elimination of risks (e.g., infrastructural risks (e.g., OI risks), procedural risks (e.g., risk of infection and contamination) that are associated with a setting in a healthcare environment. The elimination of clutter, control of major components under a unified and intuitive user interface, and the logical elimination of potential accumulated risk events (e.g., OI risks) and procedural risks are deliberately addressed, in whole or in part, by the present disclosure. The present disclosure describes the following: a pass-through logistics cabinet, an ozone sterilization system, a floor sterilization robot, and systems for controlling such components.

The invention relates to a method and apparatus for controlling the inner temperature of a patient, comprising the steps of creating a fluid circuit that comprises a patient and a heat exchanger, the power supply thereto being controlled by a controller; subjecting at least a portion of the fluid in said circuit to the heat exchanger; directing the subjected fluid to and into the patient to control the temperature of the patient; estimating the organ temperature of the patient by a model that has been obtained on a mammal other than the patient; and controlling the power supply to the heat exchanger such that the estimated organ temperature does not exceed a threshold organ temperature, potentially taking into account estimated future organ temperatures. The invention further relates to a method and apparatus for controlling the inner temperature of a patient when subject to whole body hyperthermia, and to a method for obtaining the model.

Continuous core body temperature measurements are made during hypothermic operations, where the core body temperature of the patient is lowered to reduce swelling. Caregivers monitor the patient's core body temperature to prevent damage that can occur to the patient if the patient's core body temperature becomes too low. To accurately determine the core body temperature of the patient, a temperature monitoring system measures the temperature at or near the surface of the patient and through at least a portion of a thermal block at multiple locations.

Exemplary blankets can comprise a flexible fluid-impermeable outer shell having two outer layers sealed around their perimeters, a flexible radiant barrier layer positioned inside the outer shell and being reflective of radiant energy, and a flexible thermal insulation layer positioned inside the outer shell adjacent the radiant barrier layer and comprising a material having low thermal conductivity, such that the blanket is capable of retaining patient body heat by creating a barrier to conductive, convective, and radiant patient body heat loss. Some disclosed blankets include an air cell layer or material capable of entrapping air, inside the outer shell, such as an exemplary open cell foam layer. Some disclosed blankets are MRI-compatible.

Aspects of the present disclosure relate to a warming system. The warming system includes a light device having a light source configured to be positioned proximate to a patient support having a patient support surface. The light source can also be configured to generate infrared radiation. The warming system can also include a flexible sheet having a first side configured to reflect at least some of the generated infrared radiation from the light device toward a portion of the patient support surface.

Methods of treating tumors by administering compounds to a patient are provided. Compounds such as drugs, may be administered to the patient orally, by injection, intravenously, or topically, which then accumulate as compounds such as a protoporphyrin compound in tumor cells. After such accumulation, such compounds are then activated in various aspects to treat tumors cells, thereby treating cancer. Cancers such as glioblastoma may be treated.

An integrated and modular air and lighting plenum that is the primary directional lighting mounting apparatus and laminar flow diffuser of an HVAC system in a healthcare setting. The plenum provides laminar air flow from the ceiling to the room in which it is located in accordance with HVAC requirements for healthcare environment settings, by using a plurality of cylindrical airflow outlets. The use of cylindrical airflow outlets promotes laminar airflow by reducing sharp boundaries that induce turbulence (e.g., the corners of rectangular or square outlets) and creates a highly sterile environment around the patient and staff in the operating room. The surgical lights used in the integrated air and lighting plenum allow the beam direction, spot size, focal point, brightness, and color temperature of the emitted light to be controlled.