A patient data charting system for automated data capture by an electronic patient care record (ePCR) generated during a patient encounter with emergency medical services (EMS) includes a local computing device including a processor, and a memory storing an ePCR including ePCR data fields, and a user interface device communicatively coupled to the local computing device and including a microphone and speaker, wherein the microphone may be configured to capture spoken patient encounter information, wherein the processor may be configured to receive the spoken patient encounter information as text information from a speech-to-text conversion application, determine at least one ePCR data field value based on the text information, populate at least one ePCR data field with the at least one ePCR data field value, generate caregiver prompts based on the at least one ePCR data field value, and provide the audible caregiver prompts to the caregiver via the speaker.

An indication that a patient event occurred may be used to evaluate the efficacy of at least one therapy program and/or adjust therapy delivery to the patient. In some examples, the patient event indication includes patient input that may be received via an event indication button of a programming device. In some examples, therapy delivery may be adjusted by adjusting at least one therapy parameter value, switching therapy programs or therapy program groups or restarting a therapy cycle of a medical device.

In one embodiment, a method for operating a system for management of implantable medical devices (IMDs), comprises conducting communication sessions with a plurality of clinician programmer devices while the clinician programmer devices are engaged in respective programming sessions with IMDs; receiving and storing second programming data from a plurality of clinician programmer devices, wherein the second programming data was created during programming sessions with IMDs without network connectivity to the system for management of IMDs; reconciling programming of the plurality of IMDs that were programmed with the second programming data with data stored by the system for management of IMDs; and communicating second signed validation data to cause IMDs to conduct therapeutic operations according to programming data validated by respective instances of second validation data.

Methods, devices and program products are provided and include memory to store a baseline task handling (TH) pattern and TH circuitry including one or more processors. The TH circuitry is configured to perform tasks associated with one or more of collecting one or more CA signals or environmental event signals. The TH circuitry analyzes the one or more CA signals or environmental event signals, delivers therapy, detects communications requests, or maintains communications sessions with an external device. The IMD monitors a TH characteristic in connection with the performing the tasks, compares the TH characteristic to the baseline TH pattern and implements a corrective action in response to the compare of the TH characteristic and the baseline TH pattern.

Described herein are methods, devices, and systems for providing an implantable leadless pacemaker (LP) with a remote follow-up capability whereby the LP can provide diagnostic information to an external device that is incapable of programming the LP, wherein the LP includes two or more implantable electrodes used to output both pacing pulses and conductive communication pulses. Such a method can include the LP monitoring for a presence of one or more notification conditions associated with the LP and/or associated with a patient within which the LP is implanted, and the LP periodically outputting an advertisement sequence of pulses, using at least implantable electrodes of the LP, irrespective of whether the LP recognizes the presence of at least one notification condition. The method can also include the LP recognizing the presence of at least one notification condition, and based thereon, the LP also outputting a notification sequence of pulses.

Described herein are methods, devices, and systems for providing an implantable leadless pacemaker (LP) with a remote follow-up capability whereby the LP can provide diagnostic information to an external device that is incapable of programming the LP, wherein the LP includes two or more implantable electrodes used to output both pacing pulses and conductive communication pulses. Such a method can include the LP monitoring for a presence of one or more notification conditions associated with the LP and/or associated with a patient within which the LP is implanted, and the LP periodically outputting an advertisement sequence of pulses, using at least implantable electrodes of the LP, irrespective of whether the LP recognizes the presence of at least one notification condition. The method can also include the LP recognizing the presence of at least one notification condition, and based thereon, the LP also outputting a notification sequence of pulses.

A wearable defibrillator for use in monitoring patient movement and cardiac activity and treating a patient includes a garment configured to be worn by the patient, treatment electrodes configured to apply an electric current to the patient, and an alarm module configured to provide audio, visual, and haptic notifications. The notifications are configured to indicate that an electric current will be administered imminently and prompt the patient to provide a response input. The wearable defibrillator includes a motion sensor configured to detect motion and body position of a patient, and a controller in electrical communication with the alarm module and the motion sensor. The controller is configured to monitor for the response input after the prompt, determine, based on the detected motion and body position, whether the patient is sleeping, and cause a change in one or more characteristics of the prompt on determining that the patient is sleeping.

A wearable defibrillator includes garment configured to be worn by a patient, treatment electrodes configured to apply electric current to the patient, and an alarm module configured to provide audio, visual, and haptic notifications. The notifications are configured to indicate that an electric current will be administered imminently, and prompt the patient to provide a response input. The wearable defibrillator includes a motion sensor configured to detect motion and a lack of motion of the patient, and a controller in electrical communication with the alarm module and the motion sensor. The controller is configured to monitor for the response input, cause administration of the electric current to be delayed or cancelled if the response input is received and motion of the patient is detected, and cause administration of the electric current to be delivered if no response input from the patient is received and a lack of motion is detected.

Systems and methods may use an augmented reality device during a surgical procedure. The systems and methods may use an augmented reality display of an augmented reality device to present or project a virtual feature during a surgical procedure while permitting physical aspects of a surgical field to be viewed through the augmented reality display. The virtual feature may include aspects of a preoperative plan, a surgical device, an anatomical aspect of a patient, etc.

A method and device for detecting phrenic nerve stimulation (PNS) in, or using, a cardiac medical device. A test signal sensitive to contraction of a diaphragm of a patient may be sensed and signal artifacts of the test signal within each of a first window of the test signal prior to a predetermined cardiac signal and a second window of the test signal subsequent to the predetermined cardiac signal may be determined. The PNS beat criteria may be evaluated, for example, using the test signal, which may be a heart sounds signal.