In one embodiment, a method to detect noise levels in electrocardiogram (ECG) signals is described. The method includes connecting to at least three sensing electrodes and obtaining a signal from each of the at least three sensing electrodes. The method also includes defining at least three channels between the at least three electrodes. The method includes calculating a morphological similarity value of at least one combination of the at least three channels based at least in part on the obtained signal from each of the at least three sensing electrodes and determining a noise level based at least in part on the calculated morphological similarity value.

A therapeutic device for treating an acute medical condition of a patient such as cardiac arrest is provided. The device includes one or more sensors that monitor parameters such as heart rhythm that relate to the patient's medical condition. The device also includes a plurality of medication reservoirs, each reservoir including a conduit, wherein each reservoir holds a predetermined medication that may be used to treat the condition. A manifold is connected with the reservoirs via their respective conduits. A delivery line is connected with the manifold to deliver fluids from the manifold to the patient intravenously. One or more medication pumps are in fluid connection with respective ones of the reservoirs. A processor is connected with the sensors. The processor includes a memory that stores processing instructions to interpret the parameters and to determine a recommended medication to deliver to the patient based on the parameters, the recommended medication being one of the predetermined medications. The processor is operatively connected with the medication pumps. When a recommended medication is determined, the processor actuates the medication pump connected with the reservoir including the recommended medication to deliver the medication to the patient via the manifold and the delivery line.

A serviceable wearable cardiac treatment device for continuous extended use by an ambulatory patient includes a garment, a device controller, and an ingress-protective housing. The garment is configured to dispose therein a plurality of ECG sensing and therapy electrodes to monitor for and treat a cardiac arrhythmia in the patient. The device controller is configured to be in separable electrical communication with the plurality of ECG sensing and therapy electrodes and includes an impact-resistant energy core, and first and second circuit boards affixed to opposing sides of the impact-resistant energy core. The impact-resistant energy core includes a frame and at least one capacitor permanently bonded to the frame to form a unitary mass. The ingress-protective housing is configured to enable removal of the impact-resistant energy core and the first and second circuit boards during servicing.

Temporary pacing catheters for pacing a patient’s heart and methods of use. The pacing catheter may include variable stiffness shaft. A distal portion of the pacing catheter may carry one or more electrodes for pacing the patient’s heart. The pacing catheter may include a lumen configured to receive a shaping instrument. The pacing catheter may have a first configuration when advanced to the patient’s heart without the shaping instrument and a second configuration configured to stabilize the pacing catheter within the patient’s heart when the shaping instrument is introduced through the lumen.

Systems, interfaces, and methods are described herein related to the evaluation of a patient's cardiac conduction system and evaluation of cardiac conduction system pacing therapy being delivered to the patient's cardiac conduction system. Evaluation of the patient's cardiac conduction system may utilize a plurality of breakthrough maps to determine where a cardiac conduction system block may be located. Evaluation of cardiac conduction system pacing therapy may utilize various electrical heterogeneity information monitored before and during delivery of cardiac conduction system pacing therapy.

A medical device processor is configured to receive a first cardiac electrical signal sensed from a first sensing electrode vector, receive a second cardiac electrical signal sensed from a second sensing electrode vector different than the first sensing electrode vector, and construct a third cardiac electrical signal from the first cardiac electrical signal and the second cardiac electrical signal. In some examples, the system determines sensed cardiac events according to at least one setting of a cardiac event sensing threshold control parameter from at least the third cardiac electrical signal and may determine at least one acceptable setting of a sensing control parameter based on the determined sensed cardiac events. The processor may generate an output representative of the determined sensed cardiac events.

A therapy electrode apparatus for dispensing conductive gel to skin of a patient wearing a wearable defibrillator includes a therapy electrode, at least one reservoir comprising the conductive gel, and a gel deployment device comprising at least two reactive chemicals. The at least one reservoir is configured to release the conductive gel between the therapy electrode and a patient's skin prior to a delivery of one or more therapeutic shocks. The gel deployment device configured to, on receiving a treatment signal from a controller of the wearable defibrillator operably connected to the gel deployment device, cause the at least two reactive chemicals to come into contact to produce a pressurized fluid to release the conductive gel from the at least one reservoir between the therapy electrode and the patient's skin.

The presence of a cardiac pulse in a patient is determined by evaluating physiological signals in the patient. In one embodiment, a medical device evaluates optical characteristics of light transmitted into a patient to ascertain physiological signals, such as pulsatile changes in general blood volume proximate a light detector module. Using these features, the medical device determines whether a cardiac pulse is present in the patient. The medical device may also be configured to report whether the patient is in a VF, VT, asystole, or PEA condition, in addition to being in a pulseless condition, and prompt different therapies, such as chest compressions, rescue breathing, defibrillation, and PEA-specific electrotherapy, depending on the analysis of the physiological signals. Auto-capture of a cardiac pulse using pacing stimuli is further provided.

An ambulatory medical device is provided. The ambulatory medical device includes at least one sensor configured to acquire physiological data of a patient, at least one network interface and at least one processor coupled to the at least one sensor and the at least one network interface. The at least one processor is configured to detect, via the at least one network interface, a medical device, to establish a secure communication session with the medical device via the at least one network interface, to detect a data capacity of the secure communication session, to identify a category of patient data associated with the data capacity, and to transmit patient data of the category to the medical device via the secure communication session.

The invention relates to a stimulation device for electrotherapy, in particular a defibrillator device and/or external pacemaker device, comprising at least two contact electrodes, which can be applied to the body of a patient at suitable stimulation positions and by means of which current pulses can be applied to the body of the patient, the first of the at least two contact electrodes acting as a charging electrode having positive polarity, and the second of the at least two contact electrodes acting as a discharging electrode having negative polarity with respect to an emitted current pulse, and with a current pulse generator, which is or can be connected to the contact electrodes by means of line connections. The invention further relates to a method for determining the polarity of contact electrodes applied to the body of a patient.