Response of rotary blood pumps to changes in preload and afterload at a fixed speed setting are unphysiological when compared with the natural heart.
about
Mechanical circulatory support in the new era: an overviewPreload sensitivity in cardiac assist devicesHemodynamic effects of various support modes of continuous flow LVADs on the cardiovascular system: a numerical study.In vivo testing of a novel blood pump for short-term extracorporeal life support.Continuous flow left ventricular assist devices: shared care goals of monitoring and treating patientsPreload-based starling-like control for rotary blood pumps: numerical comparison with pulsatility control and constant speed operation.Implantable continuous-flow right ventricular assist device: lessons learned in the development of a cleveland clinic device.Preload-based Starling-like control of rotary blood pumps: An in-vitro evaluation.Artificial organs 2011: a year in review.HeartWare miniaturized intrapericardial ventricular assist device: advantages and adverse events in comparison to contemporary devices.Total artificial hearts: past, present, and future.Circulatory support devices: fundamental aspects and clinical management of bleeding and thrombosis.Mechanical circulatory support devices: methods to optimize hemodynamics during use.The Effect of Compliant Inflow Cannulae on the Hemocompatibility of Rotary Blood Pump Circuits in an In Vitro Model.Application of Adaptive Starling-Like Controller to Total Artificial Heart Using Dual Rotary Blood Pumps.Rotary piston blood pumps: past developments and future potential of a unique pump type.Preservation of native aortic valve flow and full hemodynamic support with the TORVAD using a computational model of the cardiovascular system.In Vitro Evaluation of an Immediate Response Starling-Like Controller for Dual Rotary Blood Pumps.Effects of Interaction Between Ventricular Assist Device Assistance and Autoregulated Mock Circulation Including Frank-Starling Mechanism and Baroreflex.In Vivo Evaluation of Active and Passive Physiological Control Systems for Rotary Left and Right Ventricular Assist Devices.Anatomy and Physiology of Left Ventricular Suction Induced by Rotary Blood Pumps.A compliant, banded outflow cannula for decreased afterload sensitivity of rotary right ventricular assist devices.Exercise hemodynamics during extended continuous flow left ventricular assist device support: the response of systemic cardiovascular parameters and pump performance.Mechanical Circulatory Support for Advanced Heart Failure: Are We about to Witness a New "Gold Standard"?Starling-like flow control of a left ventricular assist device: in vitro validation.Exercise studies in patients with rotary blood pumps: cause, effects, and implications for starling-like control of changes in pump flow.Physiological controller of an intra-aorta pump based on baroreflex sensitivity.Mitral Valve Regurgitation with a Rotary Left Ventricular Assist Device: The Haemodynamic Effect of Inlet Cannulation Site and Speed Modulation.Evaluation of Physiological Control Systems for Rotary Left Ventricular Assist Devices: An In-Vitro Study.In Vitro Comparison of Active and Passive Physiological Control Systems for Biventricular Assist Devices.Exercise gas exchange in continuous-flow left ventricular assist device recipients.
P2860
Q26764936-C9390B87-19D8-41A2-B0E7-46A16A1D3B82Q26853212-0D30C8BA-583C-4AF8-A50E-31D7E3D117D2Q33610550-29D05312-6E55-46E1-A81B-5A6F22113518Q33899171-DF431154-CB23-4DC8-A208-14B05A172BB0Q35183409-20C33079-CC81-403C-890B-5E81AA26D86BQ35596834-2421E1F4-FE34-4F50-8484-F35DA162FC1BQ36247354-BB5C1DA2-6029-44E3-89AD-E6D66DE6C7D7Q36284120-4D6B61E6-6BE4-4FE2-BE8C-D4A5095E5418Q37991038-756608CB-E095-426F-A4A7-FAE98006F20DQ38124883-1344035D-5749-4370-9D23-7704A2A379FCQ38511060-346A520B-67D4-4B46-AAF8-A573F2150B21Q38572789-AAA522F8-F9F7-4040-B3E5-D1432AE549FEQ38690293-D50A6DB6-EE15-4659-8272-5426458A5200Q38722481-4BC47791-9B2D-4BA7-A9B9-A9BA278551A3Q38829612-48DA04CB-A0FA-4105-BF5C-7226C521FB8AQ38847481-823B6D64-F244-4B38-BC52-E922F5C5295FQ40092024-D0213A1A-3391-432C-BBEF-789E1ED5CDC7Q40109485-262FC2B2-4F42-44A4-959F-5ED47C66A8CBQ40305521-93520B90-6B8E-468E-A0B7-423ABB9DF682Q40989130-0FAB8663-1567-41B4-8015-2457EFB28399Q41610680-BC3EBA1D-21F0-4CDC-8E46-BA70EBF8AD5DQ43485783-107528CF-5610-4F62-8689-967664B8C6A1Q44555268-B6FB3961-B6E3-448D-9362-E781A725CE4CQ47556856-C9B0A0DF-A997-49B7-9CF1-A8698401C5DBQ48134848-57A192CC-8311-4AF0-8E6F-CADD778730E4Q51222925-312FCE1E-717D-4525-B93F-132E639EBA27Q51325024-53C9E64F-8E65-4A4E-B7FF-CCECF96C19FCQ51476021-3227F6EF-3C42-406E-8884-8DCC08735458Q51539440-7F830BDD-9CEE-4FE7-8AF3-FCB4C81F6A76Q51805164-98AF7D77-2F83-45AC-A46A-4157EC90FD69Q55289545-A3BD1CEE-E1DC-4952-9B17-5E1F215F22BE
P2860
Response of rotary blood pumps to changes in preload and afterload at a fixed speed setting are unphysiological when compared with the natural heart.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh-hant
name
Response of rotary blood pumps ...... mpared with the natural heart.
@en
Response of rotary blood pumps ...... mpared with the natural heart.
@nl
type
label
Response of rotary blood pumps ...... mpared with the natural heart.
@en
Response of rotary blood pumps ...... mpared with the natural heart.
@nl
prefLabel
Response of rotary blood pumps ...... mpared with the natural heart.
@en
Response of rotary blood pumps ...... mpared with the natural heart.
@nl
P2093
P2860
P1433
P1476
Response of rotary blood pumps ...... mpared with the natural heart.
@en
P2093
David G Mason
Peter J Ayre
Robert F Salamonsen
P2860
P304
P356
10.1111/J.1525-1594.2010.01168.X
P577
2011-03-01T00:00:00Z