OBJECTIVES:Atrioventricular conduction prolongation (AVCP) in cardiac pacing is measurable and results primarily from delayed atrial conduction. Noninvasive methods for measuring atrial conduction are lacking. Accordingly, AVCP was used to estimate atrial conduction and investigate its role on the paced atrioventricular delay (pAVD) during biventricular pacing (BiVP) optimization. DESIGN: Retrospective analysis of data collected as part of a randomized controlled study of temporary BiVP after cardiopulmonary bypass. SETTING:Single-center study at university-affiliated tertiary care hospital. PARTICIPANTS: Cardiac surgical patients at risk of left ventricular failure after cardiopulmonary bypass. INTERVENTIONS: Temporary BiVP was optimized immediately after cardiopulmonary bypass. Vasoactive medication and fluid infusion rates were held constant during optimization. MEASUREMENTS AND MAIN RESULTS: For each patient the AVCP and the pAVD producing the optimum (highest) cardiac output (OptCO) and mean arterial pressure (OptMAP) were determined. Patients were stratified into long- and short-AVCP groups. Overall AVCP (mean ± standard deviation) was 64 ± 28 ms. For the short-AVCP group (<64 ms, n = 3), AVCP, OptCO, and OptMAP were 40 ± 11, 120 ± 0, and 150 ± 30 ms, respectively, and for the long-AVCPgroup (>64 ms, n = 4), these same parameters were 89 ± 10, 218 ± 44, and 218 ± 29 ms. OptCO and OptMAP were significantly less in the short-AVCP group (p = 0.015 and p = 0.029, respectively). CONCLUSIONS:AVCP varies widely after cardiopulmonary bypass, affecting optimum pAVD. Failure to correct for this can result in the selection of inappropriately short and potentially deleterious pAVDs, especially when nominal pAVD is used, causing BiVP to appear ineffective. Copyright Â
RCT Entities:
OBJECTIVES:Atrioventricular conduction prolongation (AVCP) in cardiac pacing is measurable and results primarily from delayed atrial conduction. Noninvasive methods for measuring atrial conduction are lacking. Accordingly, AVCP was used to estimate atrial conduction and investigate its role on the paced atrioventricular delay (pAVD) during biventricular pacing (BiVP) optimization. DESIGN: Retrospective analysis of data collected as part of a randomized controlled study of temporary BiVP after cardiopulmonary bypass. SETTING: Single-center study at university-affiliated tertiary care hospital. PARTICIPANTS: Cardiac surgical patients at risk of left ventricular failure after cardiopulmonary bypass. INTERVENTIONS: Temporary BiVP was optimized immediately after cardiopulmonary bypass. Vasoactive medication and fluid infusion rates were held constant during optimization. MEASUREMENTS AND MAIN RESULTS: For each patient the AVCP and the pAVD producing the optimum (highest) cardiac output (OptCO) and mean arterial pressure (OptMAP) were determined. Patients were stratified into long- and short-AVCP groups. Overall AVCP (mean ± standard deviation) was 64 ± 28 ms. For the short-AVCP group (<64 ms, n = 3), AVCP, OptCO, and OptMAP were 40 ± 11, 120 ± 0, and 150 ± 30 ms, respectively, and for the long-AVCP group (>64 ms, n = 4), these same parameters were 89 ± 10, 218 ± 44, and 218 ± 29 ms. OptCO and OptMAP were significantly less in the short-AVCP group (p = 0.015 and p = 0.029, respectively). CONCLUSIONS: AVCP varies widely after cardiopulmonary bypass, affecting optimum pAVD. Failure to correct for this can result in the selection of inappropriately short and potentially deleterious pAVDs, especially when nominal pAVD is used, causing BiVP to appear ineffective. Copyright Â
Authors: William T Abraham; Westby G Fisher; Andrew L Smith; David B Delurgio; Angel R Leon; Evan Loh; Dusan Z Kocovic; Milton Packer; Alfredo L Clavell; David L Hayes; Myrvin Ellestad; Robin J Trupp; Jackie Underwood; Faith Pickering; Cindy Truex; Peggy McAtee; John Messenger Journal: N Engl J Med Date: 2002-06-13 Impact factor: 91.245
Authors: Andrew E Epstein; John P DiMarco; Kenneth A Ellenbogen; N A Mark Estes; Roger A Freedman; Leonard S Gettes; A Marc Gillinov; Gabriel Gregoratos; Stephen C Hammill; David L Hayes; Mark A Hlatky; L Kristin Newby; Richard L Page; Mark H Schoenfeld; Michael J Silka; Lynne Warner Stevenson; Michael O Sweeney; Sidney C Smith; Alice K Jacobs; Cynthia D Adams; Jeffrey L Anderson; Christopher E Buller; Mark A Creager; Steven M Ettinger; David P Faxon; Jonathan L Halperin; Loren F Hiratzka; Sharon A Hunt; Harlan M Krumholz; Frederick G Kushner; Bruce W Lytle; Rick A Nishimura; Joseph P Ornato; Richard L Page; Barbara Riegel; Lynn G Tarkington; Clyde W Yancy Journal: Circulation Date: 2008-05-15 Impact factor: 29.690
Authors: John G F Cleland; Jean-Claude Daubert; Erland Erdmann; Nick Freemantle; Daniel Gras; Lukas Kappenberger; Luigi Tavazzi Journal: N Engl J Med Date: 2005-03-07 Impact factor: 91.245
Authors: Douglas A Hettrick; David E Euler; Paul S Pagel; Shailesh K Musley; Eduardo N Warman; Paul D Ziegler; Rahul Mehra Journal: Pacing Clin Electrophysiol Date: 2002-06 Impact factor: 1.976
Authors: Jochen D Muehlschlegel; Yong G Peng; Emilio B Lobato; Philip J Hess; Tomas D Martin; Charles T Klodell Journal: J Card Surg Date: 2008 Jul-Aug Impact factor: 1.620
Authors: Henry M Spotnitz; Santos E Cabreriza; Daniel Y Wang; T Alexander Quinn; Bin Cheng; Lauren N Bedrosian; Linda Aponte-Patel; Craig R Smith Journal: Ann Thorac Surg Date: 2013-07-16 Impact factor: 4.330
Authors: Daniel Y Wang; Lauren A Kelly; Marc E Richmond; T Alexander Quinn; Bin Cheng; Michelle D Spotnitz; Santos E Cabreriza; Yoshifumi Naka; Allan S Stewart; Craig R Smith; Henry M Spotnitz Journal: Tex Heart Inst J Date: 2013