2025
Physiologic control of rotary blood pumps by ventricular chamber size estimation using resonantly coupled sensors
Wang Y, Ghali G, Luo X, Bonde P, Giridharan G. Physiologic control of rotary blood pumps by ventricular chamber size estimation using resonantly coupled sensors. Biomedical Signal Processing And Control 2025, 110: 108135. DOI: 10.1016/j.bspc.2025.108135.Peer-Reviewed Original ResearchRotary blood pumpsControl algorithmConstant pump speedEnd-diastolic volumePump speedVentricular suctionBlood pumpPhysiological control algorithmCirculatory system modelLeft ventricular end-diastolic volumeMeasurement noiseVentricular end-diastolic volumePulmonary vascular resistanceFixed pump speedHigh-efficiency sensorsLong-term driftVentricular chamber sizeProposed algorithmSensorSystem modelVascular resistanceSpeedPump-independentAlgorithmSuction
2020
Progress on Wireless LVAD and Energy Sources for Mechanical Circulatory Systems
Valdovinos J, Park J, Smith J, Bonde P. Progress on Wireless LVAD and Energy Sources for Mechanical Circulatory Systems. 2020, 609-620. DOI: 10.1007/978-3-030-47809-4_39.Peer-Reviewed Original ResearchTranscutaneous energy transfer systemWireless power transferPower transferMechanical circulatory supportEnergy systemsDevice-related infectionsPump reliabilityPulsatile blood pumpMechanical circulatory systemsEnergy transfer systemBlood pumpEnergy sourcesPump technologyMechanical circulatory support devicesHeart failure patientsCirculatory support devicesTransfer systemContinuous-flow devicesFlow deviceMCS therapyAdverse eventsFailure patientsHospital readmissionCirculatory supportDevice implantation
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