Abstract: A method of monitoring heating of a hermetic package of an implanted transcutaneous energy transfer system (TETS) coil, the method includes monitoring a power transfer between the implanted TETS coil and an external TETS coil; detecting an amount of power lost during the power transfer; determining if the amount of power lost during the power transfer is above a first predetermined threshold; if the power lost is above the first predetermined threshold, determining if a misalignment between the implanted TETS coil and the external TETS coil is greater than a predetermined distance; and if the misalignment is greater than the predetermined distance, generating an alert to align the external TETS coil with the implanted TETS coil.

Abstract: In some examples, a medical device system includes an implantable medical device (IMD) configured to be implanted underneath a skin of a patient, the IMD comprising: acoustic receiving circuitry configured to: receive one or more acoustic communication signals; and receive one or more acoustic biometric signals from the patient. The medical device system includes communication circuitry configured for wireless communication according to a communication protocol. Additionally, the medical device system includes processing circuitry configured to: receive, via the acoustic receiving circuitry, a sequence of acoustic communication signals that are separate from the one or more acoustic biometric signals; decode the sequence of acoustic communication signals to identify one or more requested actions; and control the IMD to perform the one or more requested actions.

Abstract: An example medical device includes a memory; and processing circuitry coupled to the memory, the processing circuitry is configured to: receive, from one or more electrodes coupled to the medical device, a cardiac signal; determine a risk of noise being greater than or equal to a noise risk threshold or an active amount of the noise being greater than or equal to an active noise threshold; and in response to determining the risk of noise is greater than or equal to the noise risk threshold or the active amount of noise is greater than or equal to the active noise threshold, activate a filter to filter the noise from the cardiac signal.

Abstract: An example system includes memory configured to store a plurality of lead impedances (LeadZs) and processing circuitry communicatively coupled to the memory. The processing circuitry is configured to determine a first sensed LeadZ, and determine a second sensed LeadZ. The processing circuitry is configured to determine a first difference between the first sensed LeadZ and the second sensed LeadZ, and determine a parameter based at least in part on the first difference. The first sensed LeadZ and the second sensed LeadZ are sensed during a same first cardiac cycle or adjacent cardiac cycles of a heart that is receiving pacing.

Abstract: An internal controller implantable within the body of a patient as part of a left ventricular assist device (LVAD) system and a method therefore are provided. According to one aspect, the internal controller includes processing circuitry configured to establish a radio frequency (RF) communication session with a first external power transmitter that responds to the advertisement. The processing circuitry is also configured to determine when a power transmission status of the first external power transmitter does not match a power receipt status of the internal controller, and then terminate the RF communication session with the first external power transmitter and cause the radio interface to broadcast another advertisement.

Abstract: A medical device is configured to obtain an impedance measurement and determine that a medical lead received by a connector bore of the medical device is either an integrated bipolar lead or a true bipolar lead based on the impedance measurement. The medical device is configured to select at least one operating parameter setting based on the determined medical lead type and process a cardiac electrical signal received via the medical lead according to the at least one operating parameter setting for determining a need for an electrical stimulation therapy.

Abstract: A method of controlling operation of an implantable blood pump includes attempting to restart a stopped implantable blood pump for a predetermined number of attempts with either power from an internal battery of a controller in communication with the implantable blood pump or transcutaneous energy transfer system (TETS) power in communication with the internal battery and the implantable blood pump. Following the predetermined number of attempts, the method includes pausing attempting to restart the implantable blood pump and begin attempting to recharge the internal battery with TETS power.

Abstract: In an implanted medical device system, an internal controller, external power transmitter and methods for performing battery conditioning are disclosed. According to one aspect, an internal controller includes processing circuitry configured to cause conditioning of an internal battery of the internal controller responsive to a direction from an external power transmitter in radio communication with the internal controller.

Abstract: A TETS having an external controller having a power source, a transmission coil in communication with the external controller, a receiving coil configured for transcutaneous inductive communication with the transmission coil, and an implantable controller in communication with the receiving coil and an implantable blood pump. The implantable controller has a battery configured to receive power from the receiving coil and the external controller is configured to categorize power transfer states based on predetermined thresholds of efficiency and power demand, and user display states (associated with optional configurable notifications) based on the power transfer states and predetermined temperature thresholds of the transmission coil.

Abstract: A method of managing a speed of implantable blood pump. The implantable blood pump is in communication with an internal battery and a transcutaneous energy transfer system (TETS). The method includes starting the pump at a programmed set speed. The speed of the pump is decreased from the programmed set speed to a minimum set speed if either a capacity of the internal battery is less than a predetermined reserve level and TETS power is unavailable, or there is insufficient TETS power to maintain the programmed set speed. The speed of the pump is progressively decreased from the programmed set speed if there is insufficient power to maintain the programmed set speed.

Abstract: In an implanted medical device system, an internal controller, external power transmitter and methods for performing battery conditioning are disclosed. According to one aspect, an internal controller includes processing circuitry configured to cause conditioning of an internal battery of the internal controller responsive to a direction from an external power transmitter in radio communication with the internal controller.

Abstract: A TETS having an external controller having a power source, a transmission coil in communication with the external controller, a receiving coil configured for transcutaneous inductive communication with the transmission coil, and an implantable controller in communication with the receiving coil and an implantable blood pump. The implantable controller has a battery configured to receive power from the receiving coil and the external controller is configured to categorize power transfer states based on predetermined thresholds of efficiency and power demand, and user display states (associated with optional configurable notifications) based on the power transfer states and predetermined temperature thresholds of the transmission coil.

Abstract: A method of managing a speed of implantable blood pump. The implantable blood pump is in communication with an internal battery and a transcutaneous energy transfer system (TETS). The method includes starting the pump at a programmed set speed. The speed of the pump is decreased from the programmed set speed to a minimum set speed if either a capacity of the internal battery is less than a predetermined reserve level and TETS power is unavailable, or there is insufficient TETS power to maintain the programmed set speed. The speed of the pump is progressively decreased from the programmed set speed if there is insufficient power to maintain the programmed set speed.

Abstract: A system for minimizing misalignment notifications for a TETS having an implantable blood pump, an external controller having a power source and a processing circuitry, a transmission coil in communication with the external controller, a receiving coil configured for transcutaneous inductive communication with the transmission coil, and an implantable controller in communication with the receiving coil and the implantable blood pump. The implantable controller having a power source configured to receive power from the receiving coil. The processing circuitry may be configured to: operate in a first mode where an alert is generated when a power efficiency transfer between the transmission coil and the receiving coil is below a first predetermined threshold; and operate in a second mode where the alert is only generated when the power remaining in the power source for the implantable controller is below a first predetermined power source threshold.

Abstract: In some examples, a medical device system includes an implantable medical device (IMD) configured to be implanted underneath a skin of a patient, the IMD comprising: acoustic receiving circuitry configured to: receive one or more acoustic communication signals; and receive one or more acoustic biometric signals from the patient. The medical device system includes communication circuitry configured for wireless communication according to a communication protocol. Additionally, the medical device system includes processing circuitry configured to: receive, via the acoustic receiving circuitry, a sequence of acoustic communication signals that are separate from the one or more acoustic biometric signals; decode the sequence of acoustic communication signals to identify one or more requested actions; and control the IMD to perform the one or more requested actions.

Abstract: According to one or more embodiments, a system is provided. The system includes a power device implantable within a patient for powering an implantable medical device. The power device includes a first coil configured to receive wireless power signals for powering the implantable medical device and processing circuitry configured to determine at least one measurable electrical characteristic in a plurality of electrical pathways in the power device including an electrical pathway to the first coil, and detect reduced performance in receiving wireless power signals based at least in part on the determined at least one measurable electrical characteristic.

Abstract: In an implanted medical device system, an external power transmitter and methods for adjusting a rate of search pulse transmission by an external power transmitter of an implanted medical device system are disclosed. According to one aspect, a method includes detecting a condition of the external power transmitter, and selecting among rates of transmission of search pulses based on the detected condition.

Abstract: An alignment vest for holding an external coil in a predetermined location. The alignment vest may comprise at least one attachment mechanism for holding the external coil in the predetermined location. The alignment vest may also comprise a panel having a fastening mechanism and a plurality of straps, the front panel being secured to at least one of the plurality of straps.

Abstract: An alignment garment for holding an external coil in a predetermined location. The alignment garment may comprise an attachment mechanism for holding the external coil in the predetermined location. The alignment garment may also have a plurality of straps with a first strap in the plurality of straps being secured to the attachment mechanism and a second strap of the plurality of straps being secured to the attachment mechanism.

Abstract: Systems, apparatus, methods and non-transitory computer readable media facilitating telemetry data communication security between an implantable device and an external clinician device are provided. An implantable device can include a security component configured to generate security information based on reception of a clinician telemetry session request from the clinician device via a first telemetry communication protocol. The security information can include a session identifier and a first session key, and the clinician telemetry session request can include a clinician device identifier associated with the clinician device.