Abstract: A leadwire for physiological patient monitoring is provided that transfers potentials received at a chest electrode to a data acquisition device. The leadwire includes an electrode end connectable to the chest electrode and a first conductive layer extending from the electrode end. The leadwire also has a device end connectable to a data acquisition device and a second conductive layer extending from the device end. The first conductive layer is galvanically isolated from the second conductive layer such that the first conductive layer and the second conductive layer form a capacitor.

Abstract: A method of wireless pairing electronic devices includes: receiving a pairing request; transmitting, a first wildcard token via radio communication; searching for a pre-shared token; searching for the wildcard token via radio communication; establishing a wireless connection with a first device via radio communication based on the first wildcard token in response to receiving information including the first wildcard token from the first device; establishing a wireless connection with a second device via radio communication based on the pre-shared token in response to receiving information including the pre-shared token from the second device; and establishing radio communication at a second power level in response to initiating pairing with one or more of the first device and the second device.

Abstract: A leadwire for physiological patient monitoring is provided that transfers potentials received at a chest electrode to a data acquisition device. The leadwire includes an electrode end connectable to the chest electrode and a first conductive layer extending from the electrode end. The leadwire also has a device end connectable to a data acquisition device and a second conductive layer extending from the device end. The first conductive layer is galvanically isolated from the second conductive layer such that the first conductive layer and the second conductive layer form a capacitor.

Abstract: A leadwire for physiological patient monitoring is provided that transfers potentials received at a chest electrode to a data acquisition device. The leadwire includes an electrode end connectable to the chest electrode and a first conductive layer extending from the electrode end. The leadwire also has a device end connectable to a data acquisition device and a second conductive layer extending from the device end. The first conductive layer is galvanically isolated from the second conductive layer such that the first conductive layer and the second conductive layer form a capacitor.

Abstract: Systems and methods are provided for a respiratory sensor for a medical monitoring system that does not require an internal power source. The systems and methods adjust an electrical characteristic of a respiratory sensor based on a property of interest of an airflow path, receiving an excitation signal, and generating a response based on the excitation signal and the electrical characteristic.

Abstract: A patient monitoring system having defibrillation protection includes a data acquisition device and a leadset. The data acquisition device records physiological signals from a patient, the data acquisition device having at least three receiving ports, each receiving port configured to connect to a patient connector. The leadset includes a galvanic patient connector that galvanically connects a first receiving port of the data acquisition device and the patient and at least a first capacitive patient connector and a second capacitive patient connector, wherein each capacitive patient connector capacitively couples a respective receiving port of the data acquisition device and the patient.

Abstract: A patient monitoring system comprises a data acquisition device that records physiological signals from a patient, the data acquisition device having at least 3 receiving ports, each receiving port configured to connect to a patient connector. The monitoring system further includes a galvanic patient connector that galvanically connects a first receiving port of the patient connector and the patient, and at least a first capacitive patient connector and a second capacitive patient connector. Each capacitive patient connector capacitively couples a respective receiving port of the data acquisition device and the patient.

Abstract: A computer implemented method and system are provided for verifying authenticity of a medical component endpoint. The method is under control of one or more computer systems configured with specific executable instructions. The method receives, at a local medical equipment (LME) node, a cipher message combination that includes a challenge and a corresponding valid response, the LME node is unable to independently calculate the valid response. The method conveys the challenge, from the LME node, to a medical component endpoint that includes an authentication circuit, receives a candidate response from the component endpoint, where the candidate response is generated by the authentication circuit based on the challenge and determines whether the candidate response matches the valid response from the corresponding cipher message combination. The method further authenticates the component endpoint based on whether the candidate and valid responses match.

Abstract: A leadwire for physiological patient monitoring is provided that transfers potentials received at a chest electrode to a data acquisition device. The leadwire includes an electrode end connectable to the chest electrode and a first conductive layer extending from the electrode end. The leadwire also has a device end connectable to a data acquisition device and a second conductive layer extending from the device end. The first conductive layer is galvanically isolated from the second conductive layer such that the first conductive layer and the second conductive layer form a capacitor.

Abstract: Systems and methods are provided for a respiratory sensor for a medical monitoring system that does not require an internal power source. The systems and methods adjust an electrical characteristic of a respiratory sensor based on a property of interest of an airflow path, receiving an excitation signal, and generating a response based on the excitation signal and the electrical characteristic.

Abstract: A patient monitoring system comprises a data acquisition device that records physiological signals from a patient, the data acquisition device having at least 3 receiving ports, each receiving port configured to connect to a patient connector. The monitoring system further includes a galvanic patient connector that galvanically connects a first receiving port of the patient connector and the patient, and at least a first capacitive patient connector and a second capacitive patient connector. Each capacitive patient connector capacitively couples a respective receiving port of the data acquisition device and the patient.

Abstract: A computer implemented method and system are provided for verifying authenticity of a medical component endpoint. The method is under control of one or more computer systems configured with specific executable instructions. The method receives, at a local medical equipment (LME) node, a cipher message combination that includes a challenge and a corresponding valid response, the LME node is unable to independently calculate the valid response. The method conveys the challenge, from the LME node, to a medical component endpoint that includes an authentication circuit, receives a candidate response from the component endpoint, where the candidate response is generated by the authentication circuit based on the challenge and determines whether the candidate response matches the valid response from the corresponding cipher message combination. The method further authenticates the component endpoint based on whether the candidate and valid responses match.