Abstract: This document provides methods, devices, and systems for detecting the presence, absence, or amount of one or more analytes. For example, this document provides methods for using graphene-based sensors to detect one or more analytes (e.g., proteins, nucleic acids, intact cells, intact viruses, intact microorganisms, and/or chemicals).

Abstract: This document provides methods, devices, and systems for detecting the presence, absence, or amount of one or more analytes. For example, this document provides methods for using graphene-based sensors to detect one or more analytes (e.g., proteins, nucleic acids, intact cells, intact viruses, intact microorganisms, and/or chemicals).

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least one other device different from the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, and a control circuit electrically coupled to the communication circuit and the locating circuit. The control circuit is configured to determine whether the determined location imposes a limit on functionality of an implantable device, and provide user access to an implantable device feature according to the determined location.

Abstract: This document provides methods, devices, and systems for detecting the presence, absence, or amount of one or more analytes. For example, this document provides methods for using graphene-based sensors to detect one or more analytes (e.g., proteins, nucleic acids, intact cells, intact viruses, intact microorganisms, and/or chemicals).

Abstract: A portable source medical device determines communication links of a network presently available to effect communications with a target component when the source medical device is at each of a multiplicity of geographical locations. A profile is generated comprising information about each available communication link and attributes associated with each available communication link for each geographical location. When the source medical device is at a particular geographical location, a profile associated with the particular geographical location is accessed and a network connection is established between the source medical device and the target component using a communication link associated with the particular profile. Medical information is transferred between the source medical device and the target component via the communication link associated with the particular profile.

Abstract: A system including an implantable medical device (IMD) configured to be programmed with magnetic resonance imaging (MRI) settings for use during an MRI scan, a server configured to receive MRI settings associated with the IMD, and configured to store the MRI settings associated with the IMD, and a portable retrieval programmer. The portable retrieval programmer includes a housing configured for portability by a user, a first communication module in the housing configured to communicate with the server to retrieve the MRI settings associated with the IMD, and a device communication module connectible to and disconnectible from the housing and configured to communicate with the IMD to retrieve the identity data and program the IMD with the MRI settings.

Abstract: A system including an implantable medical device (IMD) configured to be programmed with magnetic resonance imaging (MRI) settings for use during an MRI scan, a server configured to receive MRI settings associated with the IMD, and configured to store the MRI settings associated with the IMD, and a portable retrieval programmer. The portable retrieval programmer includes a housing configured for portability by a user, a first communication module in the housing configured to communicate with the server to retrieve the MRI settings associated with the IMD, and a device communication module connectible to and disconnectible from the housing and configured to communicate with the IMD to retrieve the identity data and program the IMD with the MRI settings.

Abstract: A system including an implantable medical device (IMD) configured to be programmed with magnetic resonance imaging (MRI) settings for use during an MRI scan, a server configured to receive MRI settings associated with the IMD, and configured to store the MRI settings associated with the IMD, and a portable retrieval programmer. The portable retrieval programmer includes a housing configured for portability by a user, a first communication module in the housing configured to communicate with the server to retrieve the MRI settings associated with the IMD, and a device communication module connectible to and disconnectible from the housing and configured to communicate with the IMD to retrieve the identity data and program the IMD with the MRI settings.

Abstract: A system including an implantable medical device (IMD) configured to be programmed with magnetic resonance imaging (MRI) settings for use during an MRI scan, a server configured to receive MRI settings associated with the IMD, and configured to store the MRI settings associated with the IMD, and a portable retrieval programmer. The portable retrieval programmer includes a housing configured for portability by a user, a first communication module in the housing configured to communicate with the server to retrieve the MRI settings associated with the IMD, and a device communication module connectible to and disconnectible from the housing and configured to communicate with the IMD to retrieve the identity data and program the IMD with the MRI settings.

Abstract: A system and method are described herein including an implantable medical device (IMD) configured to be programmed with magnetic resonance imaging (MRI) settings for use during an MRI scan, wherein the IMD stores identity data that uniquely identifies the IMD or a patient having the IMD. The system includes an external storage media configured to receive MRI settings associated with the IMD and configured to store the MRI settings associated with the IMD. The system also includes a programmer configured to retrieve identity data from IMD, retrieve MRI settings associated with the IMD from the external storage media and program the IMD using the MRI settings.

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least a third device separate from the external device and the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, a port configured to receive user identity information into the external device, and a control circuit electrically coupled to the communication circuit, the locating circuit, and the port. The control circuit is configured to allow user access to an implantable device feature according to the determined location and received user identity information.

Abstract: A communicator facilitates communications with a remote server via a wireless network supporting a plurality of disparate data transport mechanisms having differing characteristics. A processor coupled to memory is disposed in a communicator housing, which is configured for portability. The memory stores wireless radio firmware and data transfer instructions that are executable by the processor for transferring data to the remote server in accordance with a priority level. The priority level is based in part on criticality of the data and the communicator status. A radio disposed in the housing effects communications via the wireless network in accordance with the firmware. A power source in the housing supplies power for communicator components. The processor executes program instructions for selecting a data transport mechanism among the plurality transport mechanisms based on the priority level, and transmits the data via the wireless network via the radio using the selected transport mechanism.

Abstract: A communicator facilitates communications with a remote server via a wireless network supporting a plurality of disparate data transport mechanisms having differing characteristics. A processor coupled to memory is disposed in a communicator housing, which is configured for portability. The memory stores wireless radio firmware and data transfer instructions that are executable by the processor for transferring data to the remote server in accordance with a priority level. The priority level is based in part on criticality of the data and the communicator status. A radio disposed in the housing effects communications via the wireless network in accordance with the firmware. A power source in the housing supplies power for communicator components. The processor executes program instructions for selecting a data transport mechanism among the plurality transport mechanisms based on the priority level, and transmits the data via the wireless network via the radio using the selected transport mechanism.

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least a third device separate from the external device and the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, a port configured to receive user identity information into the external device, and a control circuit electrically coupled to the communication circuit, the locating circuit, and the port. The control circuit is configured to allow user access to an implantable device feature according to the determined location and received user identity information.

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least a third device separate from the external device and the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, a port configured to receive user identity information into the external device, and a control circuit electrically coupled to the communication circuit, the locating circuit, and the port. The control circuit is configured to allow user access to an implantable device feature according to the determined location and received user identity information.

Abstract: A communicator facilitates communications with a remote server via a wireless network supporting a plurality of disparate data transport mechanisms having differing characteristics. A processor coupled to memory is disposed in a communicator housing, which is configured for portability. The memory stores wireless radio firmware and data transfer instructions that are executable by the processor for transferring data to the remote server in accordance with a priority level. The priority level is based in part on criticality of the data and the communicator status. A radio disposed in the housing effects communications via the wireless network in accordance with the firmware. A power source in the housing supplies power for communicator components. The processor executes program instructions for selecting a data transport mechanism among the plurality transport mechanisms based on the priority level, and transmits the data via the wireless network via the radio using the selected transport mechanism.

Abstract: A portable housing supports a processor coupled to memory for storing medical firmware and wireless radio firmware, first and second radios, a processor, and a power source. Communications are effected between an implantable medical device and the first radio in accordance with program instructions of the medical firmware, and between the second radio and the wireless network in accordance with program instructions of the wireless radio firmware. The first and second radios are configured to operate cooperatively in a first testing configuration, by which the first radio operates as a transmitter and the second radio operates as a receiver, and cooperatively in a second testing configuration, by which the second radio operates as a transmitter and the first radio operates as a receiver. Functional testing of the first and second radios is implemented using one or both of the first and second testing configurations.

Abstract: A communicator facilitates communications with a remote server via a wireless network supporting a plurality of disparate data transport mechanisms having differing characteristics. A processor coupled to memory is disposed in a communicator housing, which is configured for portability. The memory stores wireless radio firmware and data transfer instructions that are executable by the processor for transferring data to the remote server in accordance with a priority level. The priority level is based in part on criticality of the data and the communicator status. A radio disposed in the housing effects communications via the wireless network in accordance with the firmware. A power source in the housing supplies power for communicator components. The processor executes program instructions for selecting a data transport mechanism among the plurality transport mechanisms based on the priority level, and transmits the data via the wireless network via the radio using the selected transport mechanism.

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least a third device separate from the external device and the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, a port configured to receive user identity information into the external device, and a control circuit electrically coupled to the communication circuit, the locating circuit, and the port. The control circuit is configured to allow user access to an implantable device feature according to the determined location and received user identity information.

Abstract: An apparatus comprises an external device for communication with an implantable device. The external device includes a communication circuit configured to receive a communication signal from at least one other device different from the implantable device, a locating circuit configured to determine a location of the external device using the received communication signal, and a control circuit electrically coupled to the communication circuit and the locating circuit. The control circuit is configured to determine whether the determined location imposes a limit on functionality of an implantable device, and provide user access to an implantable device feature according to the determined location.