Unlocking the box: basic requirements for an ideal ventricular assist device controller

ABSTRACT Introduction: A modern ventricular assist device (VAD) system comprises an implantable rotary blood pump and external components located outside the patient’s body: a wearable controller connected to the pump via a percutaneous cable, wearable rechargeable batteries, battery charger, alternating- and direct-current power supplies, and a hospital device to control and monitor the system. If the blood pump is the ‘heart’ of a VAD system, the controller is its ‘brain.’ The controller drives the pump’s electrical motor; varies the pump speed or flow based on user commands or feedback signals; collects, processes, and stores data; performs self-diagnostics; transmits to and receives data from other system components, i.e., hospital monitor and batteries; and provides various types of user interface – audible, visual, and tactile. Areas covered: Here we describe the essential functions and basic design of the VAD external controller and give our views on the future of this technology. Expert commentary: Controllers for VAD systems are crucial to their successful operation. The current clinically available system comprises an external power supply and patient-friendly controller unit. Future controller solutions may enable remote hospital monitoring, more intuitive system interface, and the potential to use a single controller to automatically control a biventricular assist device configuration.

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