Abstract: The present disclosure relates, at least in part, to mycobacterial polynucleotides and polypeptides, to fragments or variants thereof, to cells comprising the mycobacterial polynucleotides and polypeptides, to cells comprising the mycobacterial polynucleotides and polypeptides, that are engineered to expand T-cells ex vivo, and to methods of use thereof.

Abstract: Safe, rapid and efficient methods for producing virus-specific or other antigen-specific T-cells from cord blood and other samples containing naive immune cells.

Abstract: Systems and methods are disclosed for facilitating communications in heterogeneous networks that include different data networks. A gateway device is configured to communicate with a first network using a TSCH protocol and with a second network using a channel hopping CSMA protocol. The gateway device can determine, during a first part of a TSCH timeslot, whether a message is received from the first network. If no message is received, the gateway device switches to the second network during a second part of the timeslot. If the gateway device receives a message from the second network, the gateway device may continue to receive the message. The receipt of the message in the second network may continue into a subsequent TSCH timeslot or may be interrupted if certain conditions are met.

Abstract: Systems and methods presented herein include a venue system that includes a guest recognition system configured to recognize one or more guests in a venue, and a guest experience analysis system configured to receive data relating to the recognized one or more guests from the guest recognition system, to generate guest experience information relating to the recognized one or more guests based at least in part on the received data relating to the recognized one or more guests, and to transmit the guest experience information relating to the recognized one or more guests to an augmented reality display device for display on an augmented reality display of the augmented reality display device.

Abstract: The present disclosure provides for isolated and processed cell therapeutic compositions and Methods of using those compositions for the treatment of a patient undergoing a hematopoietic stem cell transplant (HSCT). In some embodiments, the disclosure provides for methods of making these cells by exposing the isolated T cell populations to one or more tumor antigens.

Abstract: A multi-radio border router for synchronizing communications of multiple border router radios is provided. For example, the border router includes a border router component connected to each of the plurality of border router radios. The border router component configured for selecting one of the plurality of border router radios as a master radio and assigning channel offset parameters for each of the plurality of border router radios. The master radio is configured for broadcasting synchronization beacons based on which the non-master radios synchronize their respective clocks with that of the master radio. After the synchronization, each of the border router radios communicates with endpoints associated therewith according to a channel hopping pattern modified by applying a channel offset determined based on the channel offset parameters assigned to the respective radio.

Abstract: The present invention provides isolated cell compositions for the treatment of cancer, including hematological and solid tumors, comprising a selected, fixed ratio of multiple ex vivo activated lymphocytic cell subsets, including specific immune effector cells directed to specific tumor associated antigens (TAAs), viral associated tumor antigens (VATA), glycolipids, or a combination thereof. By selecting specific fixed ratios of different lymphocytic cell subsets, an immune response which is comprehensive and broad pin biological and immune effector function is provided, enhancing the ability of the administered cells to mount an effective and robust immune response.

Abstract: Systems and methods are disclosed for facilitating communications in heterogeneous networks that include different data networks. A gateway device is configured to communicate with a first network using a TSCH protocol and with a second network using a channel hopping CSMA protocol. The gateway device can determine, during a first part of a TSCH timeslot, whether a message is received from the first network. If no message is received, the gateway device switches to the second network during a second part of the timeslot. If the gateway device receives a message from the second network, the gateway device may continue to receive the message. The receipt of the message in the second network may continue into a subsequent TSCH timeslot or may be interrupted if certain conditions are met.

Abstract: The present disclosure relates to thermal management of wireless access points including local thermal management, cloud-based thermal management, and thermal management based on optimization and operation such as in a distributed Wi-Fi network. The objective of the present disclosure is for thermal management in access points allowing small form-factors and aesthetic designs, preventing overheating and without requiring reduced performance or reduced hardware. Generally, the systems and methods detect when access points are nearing overheating and alter their operation so as to minimize the reduction of performance in the network while reducing power consumption.

Abstract: Systems and methods are disclosed for reconstructing a personal area network (“PAN”) after a failure in a system or network. A method can include detecting, by a node, a power failure in a system. The method can further include storing, by the node, data about a parent node in the system at a time of the power failure. The method can further include detecting, by the node, power restoration in the system and entering a restoration state in response to detecting the power restoration. The method can further include transmitting, by the node and to the parent node, an enhanced beacon request via a particular frequency channel associated with the parent node. The method can also include receiving, by the node, an acknowledgment response from the parent node via the frequency channel and receiving, by the node, an enhanced beacon request from the parent node via the frequency channel.

Abstract: Aspects and examples are disclosed for apparatuses and processes for establishing a communication link between a network using a routing protocol for low power and lossy networks (RPL) and a non-RPL-enabled device. For instance, a communication link establishment method includes establishing, by a routing protocol for low power and lossy networks (RPL) enabled device, a communication link with a non-RPL-enabled device. The method also includes establishing, by the RPL-enabled device, a network connection with an RPL-enabled network. Further, the method includes providing, by the RPL-enabled device, a proxy communication link between the non-RPL-enabled device and the RPL-enabled network. Providing the proxy communication link includes assigning a globally unique address (GUA) to the non-RPL-enabled device, and transmitting, by the RPL-enabled device, a proxy destination advertisement object to the RPL-enabled network where the proxy destination advertisement object comprises the GUA.

Abstract: A method for transmitting unicast messages includes: obtaining, by a first node configured to communicate on a primary time-slotted channel hopping (TSCH) network, a media access control (MAC) address of a second node configured to communicate on the primary TSCH network; determining whether the first node and the second node are also configured to communicate on a secondary TSCH network; and in response to determining that the first node and the second node are also configured to communicate on the secondary TSCH network: offsetting transmission of a unicast message until a second portion of a timeslot for the primary TSCH network; synchronizing to a channel hopping sequence and frequency of the secondary TSCH network for the second node, and transmitting, by the first node, the unicast message to the second node on the secondary TSCH network during the second portion of the timeslot.

Abstract: A method for transmitting unicast messages includes: obtaining, by a first node configured to communicate on a primary time-slotted channel hopping (TSCH) network, a media access control (MAC) address of a second node configured to communicate on the primary TSCH network; determining whether the first node and the second node are also configured to communicate on a secondary TSCH network; and in response to determining that the first node and the second node are also configured to communicate on the secondary TSCH network: offsetting transmission of a unicast message until a second portion of a timeslot for the primary TSCH network; synchronizing to a channel hopping sequence and frequency of the secondary TSCH network for the second node, and transmitting, by the first node, the unicast message to the second node on the secondary TSCH network during the second portion of the timeslot.

Abstract: Systems and methods are disclosed for reconstructing a personal area network (“PAN”) after a failure in a system or network. A method can include detecting, by a node, a power failure in a system. The method can further include storing, by the node, data about a parent node in the system at a time of the power failure. The method can further include detecting, by the node, power restoration in the system and entering a restoration state in response to detecting the power restoration. The method can further include transmitting, by the node and to the parent node, an enhanced beacon request via a particular frequency channel associated with the parent node. The method can also include receiving, by the node, an acknowledgement response from the parent node via the frequency channel and receiving, by the node, an enhanced beacon request from the parent node via the frequency channel.

Abstract: Systems and methods are disclosed for reconstructing a personal area network (“PAN”) after a failure in a system or network. A method can include detecting, by a node, a power failure in a system. The method can further include storing, by the node, data about a parent node in the system at a time of the power failure. The method can further include detecting, by the node, power restoration in the system and entering a restoration state in response to detecting the power restoration. The method can further include transmitting, by the node and to the parent node, an enhanced beacon request via a particular frequency channel associated with the parent node. The method can also include receiving, by the node, an acknowledgement response from the parent node via the frequency channel and receiving, by the node, an enhanced beacon request from the parent node via the frequency channel.

Abstract: Systems and methods for managing nodes in mesh networks are provided. A parent node may switch PANs and coordinate the switch with its child nodes. The parent node and its child nodes may maintain timing synchronization information for a current PAN and a new PAN. The parent node and its child nodes may switch to the new PAN using the same switching time.

Abstract: Systems and methods optimize broadcast transmissions from a parent device operating on a time-slotted channel hopping (TSCH) network to one or more low-energy endpoint devices connected and synchronized to the communications of the TSCH parent device. As part of a Receiver Initiated Transmit (RIT) communication process, the TSCH parent device receives a check-in communication from a connected low-energy endpoint device during a wake state of a wake/sleep cycle of the low-energy endpoint device. In response to the check-in message, the TSCH parent device transmits an acknowledgment message identifying a broadcast timeslot during which the TSCH parent device will broadcast stored broadcast messages. During the identified timeslot, the TSCH parent device broadcasts stored broadcast messages to any connected low-energy endpoint devices that are tuned in to the corresponding frequency channel according to the TSCH protocol.

Abstract: Systems and methods for managing nodes in mesh networks are provided. A critical node may determine a status of a backhaul connection prior to joining a PAN. A critical path may be created and maintained that includes the critical node and any intervening nodes between the critical node and the root. A critical node may switch PANs when a backhaul connection becomes unavailable. The switch may be facilitated by a node on the critical path other than the critical node. A node may switch PANs and coordinate the switch with its child nodes.

Abstract: Systems and methods for managing nodes in mesh networks are provided. A parent node may switch PANs and coordinate the switch with its child nodes. The parent node and its child nodes may maintain timing synchronization information for a current PAN and a new PAN. The parent node and its child nodes may switch to the new PAN using the same switching time.

Abstract: Systems and methods for managing nodes in mesh networks are provided. An information element may be provided to indicate a status of a backhaul connection. A critical node may use the information element to determine the status of the backhaul connection prior to joining a PAN. A critical path may be created and maintained that includes the critical node and any intervening nodes between the critical node and the root. A critical node may switch PANs when a backhaul connection becomes unavailable. The switch may be facilitated by a node on the critical path other than the critical node. The loss of backhaul connection may be determined by examining the information element. A node may switch PANs and coordinate the switch with its child nodes.