R
Robert H. Bartlett
Researcher at University of Michigan
Publications - 569
Citations - 28295
Robert H. Bartlett is an academic researcher from University of Michigan. The author has contributed to research in topics: Extracorporeal membrane oxygenation & Extracorporeal. The author has an hindex of 81, co-authored 550 publications receiving 25619 citations. Previous affiliations of Robert H. Bartlett include University of California, Irvine & NewYork–Presbyterian Hospital.
Papers
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Journal ArticleDOI
Method of pulmonary and membrane lung gas exchange measurement during extracorporeal membrane oxygenation.
Robert E. Cilley,John R. Wesley,Joseph B. Zwischenberger,John M. Toomasian,Robert H. Bartlett +4 more
TL;DR: A method for measuring simultaneous MemL and NatL gas exchange during neonatal ECMO has been described and it demonstrated minimal pulmonary gas exchange at low airway pressures and measured the gas exchange of metabolism in these critically ill neonates.
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Development of an Ex-Situ Limb Perfusion System for a Rodent Model.
TL;DR: This study is the first to document the ex-situ hind limb perfusion platform on a rodent model and has potential to guide future research to extend the viable duration of VCA preservation.
Journal ArticleDOI
Extracorporeal oxygenation in neonates.
TL;DR: For the small minority of infants who do not respond to the current mechanical ventilation regimen, the treatment of choice is now extracorporeal oxygenation, administered by a modified version of the heart-lung machine.
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Metabolic studies in head injury patients: a preliminary report.
TL;DR: Lower caloric deficits were associated with better neurologic outcomes and large caloric deficits developed by the fourth or fifth day after injury when supplementation was inadequate.
Journal ArticleDOI
An investigation of pulsatile flow past two cylinders as a model of blood flow in an artificial lung
TL;DR: Pulsatile flow across two circular cylinders with different geometric arrangements is studied experimentally using the particle image velocimetry method and numerically using the finite element method to optimize gas transfer and fluid mechanical impedance for a total artificial lung.