Nicole Berndsen scite author profile

Transcatheter patent ductus arteriosus closure (TCPC) is an emerging treatment for low birth weight extremely premature neonates (EPNs). Left pulmonary artery (LPA) and descending aorta (DAO) obstruction are described device-related complications, however, data on mid- and long-term vascular outcomes are lacking. A retrospective analysis of EPNs who underwent successful TCPC at our institution from 03/2013 to 12/2018 was performed. Two-dimensional echocardiography and spectral Doppler velocities from various time points before and after TCPC were used to identify LPA and DAO flow disturbances. A total of 44 EPNs underwent successful TCPC at a median (range) procedural weight of 1150 g (755–2500 g). Thirty-two (73%) patients were closed with the AVP II and 12 (27%) with the Amplatzer Piccolo device. LPA and DAO velocities on average remained within normal limits and improved spontaneously in long-term follow up (26.1 months, range 1–75 months). One patient, who had concerning LPA flow characteristics immediately after device implant (peak velocity 2.6 m/s) developed progressive LPA stenosis requiring stent placement 3 months post-procedure. In the remaining infants, including 7 (16%) who developed LPA and 3 (7%) who developed DAO flow disturbances (range 2–2.4 m/s), all had progressive normalization of flow velocities over time. TCPC can be performed safely in EPNs with a low incidence of LPA and DAO obstruction. In the absence of significant progressive vascular obstruction in the early post-procedure period, mild increases in LPA and DAO flow velocities tend to improve spontaneously and normalize in long-term follow-up.

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Making Perioperative Handoff Communication Count by Improving Safety and Quality in a New Congenital Heart Program

Nawathe

Berndsen

Sivarajan

et al. 2017

Journal of the American College of Cardiology

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In Situ Interprofessional Simulation in the Congenital Cardiac Intensive Care Unit Using the PEARLS Framework for Systems Integration

Parker

Rice

Cohen

et al. 2021

Proceedings of the International Symposium on Human Factors and

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We developed an in-situ interprofessional simulation program to study system factors to establish a congenital cardiac arrest activation tree and test it using human factors engineering principles. We used the Systems Engineering Initiative for Patient Safety (SEIPS) 2.0 model to understand the structure, processes, and outcomes related to the congenital cardiac arrest activation tree (CCCAT) and discuss the Promoting Excellence and Reflective Learning in Simulation (PEARLS) for systems integration framework for our systems focused debriefing (SFD).

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Nicole Berndsen

Comprehensive blood conservation program in a new congenital cardiac surgical program allows bloodless surgery for the Jehovah Witness and a reduction for all patients

Fate of the Left Pulmonary Artery and Thoracic Aorta After Transcatheter Patent Ductus Arteriosus Closure in Low Birth Weight Premature Infants

Making Perioperative Handoff Communication Count by Improving Safety and Quality in a New Congenital Heart Program

In Situ Interprofessional Simulation in the Congenital Cardiac Intensive Care Unit Using the PEARLS Framework for Systems Integration

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