Abstract: An RF module and method include a base with a probe, a reader unit, a communications unit, and a control unit that establish tracking activation EM field into a container having electrically-conductive walls. RFID tags attached to medical articles located within the container are activated and produce identification signals. The probe and base receive the identification signals and provide identification data related to medical articles located within the container. The RF module is self-contained excepting power and a data connection with which to operate. Where an Ethernet is used, power is obtained by PoE. The RF module is used to retrofit existing medication containers and may be used during the construction of a new medication container.

Abstract: A system and method for managing the contents of a medical storage container such as a tray that has a required inventory of medical articles. A Faraday cage enclosure is used to isolate, scan, and inventory the container. The container and each of the medical articles in the container have a respective RFID tag. A processor is programmed to retrieve the inventory list for the container based on its tag and compare the actual contents of the container according to their tags to the inventory list. Missing items and extra items are noted.

Abstract: A modular system of medical article containers is used to form enclosures of selectable storage space. The containers are each RF shielded and include an interconnect wall for connecting to another container to form the enclosure. The interconnect walls have a complementary design. The interconnect seam of two containers includes an electrically conductive component that also interconnects the RF shields of the two containers together. The interconnect seam also includes a tortuous path seal for greater RF shielding of the enclosure. The walls of the containers include a substrate of non-electrically conductive material for weight reduction and an electrically conductive element that is coextensive with the substrate. One embodiment is a plastic substrate with a metallic mesh. The enclosure provides a Faraday cage about the interconnected containers. Enclosures of differing heights and sizes can be made, and they may be stacked or otherwise assembled.

Abstract: A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

Abstract: A system and method for managing the contents of a medical storage container such as a tray that has a required inventory of medical articles. A Faraday cage enclosure is used to isolate, scan, and inventory the container. The container and each of the medical articles in the container have a respective RFID tag. A processor is programmed to retrieve the inventory list for the container based on its tag and compare the actual contents of the container according to their tags to the inventory list. Missing items and extra items are noted.

Abstract: A system and method for the supply of a medical storage container that has a required inventory of medical articles. An enclosure is used to isolate, scan, and inventory a tray or other container of medical articles. The container and each of the medical articles stored in the container having a wireless identification device. A probe injects activation energy and receives identification data in the enclosure. A program compares the scanned identification of the tray and the inventory of the tray to the required inventory list for the tray and indicates any differences. Extra articles and expired and recalled articles are identified. Text and graphical data displays of inventory are provided. Selectable periods for expiration of medical articles are also provided.

Abstract: A system and method for tracking medical articles, each medical article having an RFID tag. The medical articles are located in an EM shielded container that includes an injection probe that injects RFID activation energy into the container. The injection probe comprises a main conductive element having capacitive coupling forming an electric field in the container and comprises spacing above a ground plane to form a magnetic field in the container, both fields being located in the interior of the container to activate RFID tags located therein.

Abstract: An RF module and method include a base with a probe, a reader unit, a communications unit, and a control unit that establish tracking activation EM field into a container having electrically-conductive walls. RFID tags attached to medical articles located within the container are activated and produce identification signals. The probe and base receive the identification signals and provide identification data related to medical articles located within the container. The RF module is self-contained excepting power and a data connection with which to operate. Where an Ethernet is used, power is obtained by PoE. The RF module is used to retrofit existing medication containers and may be used during the construction of a new medication container.

Abstract: A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

Abstract: An RF module includes a base with a probe, a reader unit, a communications unit, and a control unit that establish an EM field into a container having electrically-conductive walls. RFID tags attached to medical articles located within the container are activated and produce identification signals. The probe and base receive the identification signals and provide identification data related to medical articles located within the container. The RF module is self-contained in that it needs only power and a data connection with which to operate. Where an Ethernet is used, power is obtained by PoE. The RF module is used to retrofit existing medication containers or may be used during the construction of a new medication container.

Abstract: A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

Abstract: A system and method for tracking medical articles, each medical article having an RFID tag. The medical articles are located in an EM shielded container that includes an injection probe that injects RFID activation energy into the container. The injection probe comprises a main conductive element having capacitive coupling forming an electric field in the container and comprises spacing above a ground plane to form a magnetic field in the container, both fields being located in the interior of the container to activate RFID tags located therein.

Abstract: A system and method for tracking medical articles, each having an RFID tag. The articles located in an EM shielded container that includes a probe that comprises a main conductive element having capacitive coupling across a slot to form an electric field and spacing above a ground plane to form an equally strong or stronger magnetic field, both fields filling the interior of the container to activate RFID tags therein. A parasitic element controls the energy pattern of the probe.

Abstract: A system and method for the supply of a medical storage container that has a required inventory of medical articles. An enclosure is used to isolate, scan, and inventory a tray or other container of medical articles. The container and each of the medical articles stored in the container having a wireless identification device. A probe injects activation energy and receives identification data in the enclosure. A program compares the scanned identification of the tray and the inventory of the tray to the required inventory list for the tray and indicates any differences. Extra articles and expired and recalled articles are identified. Text and graphical data displays of inventory are provided. Selectable periods for expiration of medical articles are also provided.

Abstract: An RF module includes a base with a probe, a reader unit, a communications unit, and a control unit that establish an EM field into a container having electrically-conductive walls. RFID tags attached to medical articles located within the container are activated and produce identification signals. The probe and base receive the identification signals and provide identification data related to medical articles located within the container. The RF module is self-contained in that it needs only power and a data connection with which to operate. Where an Ethernet is used, power is obtained by PoE. The RF module is used to retrofit existing medication containers or may be used during the construction of a new medication container.

Abstract: A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

Abstract: A system and method for tracking medical articles, each having an RFID tag. The articles located in an EM shielded container that includes a probe that comprises a main conductive element having capacitive coupling across a slot to form an electric field and spacing above a ground plane to form an equally strong or stronger magnetic field, both fields filling the interior of the container to activate RFID tags therein. A parasitic element controls the energy pattern of the probe.

Abstract: A wireless identification system and method used for identifying medical vials having a metallic crimp includes an RFID tag having a first antenna element located at the crimp so as to be capacitively coupled to the crimp to increase the effective surface area of the RFID antenna, and a second antenna element mounted to the side of the vial between the ends of the labeling mounted on the vial so as to not mask any visually readable information of the labeling. Dielectric adhesive is used in one embodiment to couple the antenna element to the crimp. The invention is particularly useful for small vials. A manufacturing method in which the wireless tag is an integral part of the container is disclosed.

Abstract: A system and method for monitoring the inventory of a medical storage container such as a tray that has a required inventory of medical articles. An enclosure is used to isolate, scan, and take an inventory of the tray or other container of medical articles. The tray and each of the medical articles in the tray have RFID tags. The enclosure having a size differing from the size needed for a resonant frequency at the RFID frequency of operation of the tags. A probe is used to create a robust electromagnetic field standing wave of constructive interference in the enclosure and a program compares the scanned present inventory of the tray to the required inventory database and indicates any differences. Expired and recalled articles and substitutes for recalled articles are identified.

Abstract: A retrofit self-contained RFID-enabling module for automatically identifying and tracking medical articles having RF tags located in a container having electrically-conductive walls includes a base having a probe mounted to the base for injecting activating rf energy into the container in which the module has been mounted. The base also includes a reader board that controls the probe between an injection mode, in which it injects RFID tag activation energy into the container to activate the tags on the medical articles, and a non-injecting mode during which the identification signals of the activated RFID tags on the medical articles can be read. The module is self-contained in that only power is needed to operate. The size of the module, including its components, is selected in relation to the size of the container so that the module may be “dropped into” the container.