Tasneem Z Naqvi1, Asim M Rafique. 1. Cardiac Non Invasive Laboratory, Cedars-Sinai Medical Center, UCLA David Geffen School of Medicine, Los Angeles, CA 90033, USA.
Abstract
BACKGROUND: Biventricular (Biv) pacemaker optimization is underused because of time and echo skill required. We evaluated radial artery tonometry during echo-guided Biv optimization of atrioventricular (AV) and interventricular (VV) delays. METHODS AND RESULTS: A total of 60 patients (67 +/- 10 years) underwent simultaneous radial artery tonometry and echocardiography after Biv implant at baseline, short AV delay, and optimal AV delay. Twenty of these also underwent VV optimization. Optimal AV delay was determined by ejection duration (E-dur) of left ventricular (LV) outflow tract by pulsed-waved (PW) Doppler (LV(E-dur)) and mitral inflow PW Doppler pattern and optimal VV delay by LV(E-dur) and tissue Doppler. E-dur was also measured from radial artery pulse wave (RA(E-dur)). AV optimization improved LV(E-dur) from 249 +/- 35 to 260 +/- 38 ms (P < .01) and RA(E-dur) from 276 +/- 31 ms to 284 +/- 32 ms (P = .02). Correlation between LV(E-dur) and by RA(E-dur) was 0.83 (95% CI 0.75-0.92). RA(E-dur) was 282.53 +/- 30 at baseline, 286.65 +/- 36 at optimal AV delay (P < .04 vs. baseline) and 286.90 +/- 35 ms (P < .04 vs. baseline) at optimal AV and VV delay in those who underwent VV optimization. CONCLUSIONS: AV and VV optimization by echocardiography produces significant improvement in LV(E-dur) and RA(E-dur). Radial artery tonometry may provide a simple noninvasive method to assist in AV delay optimization.
BACKGROUND: Biventricular (Biv) pacemaker optimization is underused because of time and echo skill required. We evaluated radial artery tonometry during echo-guided Biv optimization of atrioventricular (AV) and interventricular (VV) delays. METHODS AND RESULTS: A total of 60 patients (67 +/- 10 years) underwent simultaneous radial artery tonometry and echocardiography after Biv implant at baseline, short AV delay, and optimal AV delay. Twenty of these also underwent VV optimization. Optimal AV delay was determined by ejection duration (E-dur) of left ventricular (LV) outflow tract by pulsed-waved (PW) Doppler (LV(E-dur)) and mitral inflow PW Doppler pattern and optimal VV delay by LV(E-dur) and tissue Doppler. E-dur was also measured from radial artery pulse wave (RA(E-dur)). AV optimization improved LV(E-dur) from 249 +/- 35 to 260 +/- 38 ms (P < .01) and RA(E-dur) from 276 +/- 31 ms to 284 +/- 32 ms (P = .02). Correlation between LV(E-dur) and by RA(E-dur) was 0.83 (95% CI 0.75-0.92). RA(E-dur) was 282.53 +/- 30 at baseline, 286.65 +/- 36 at optimal AV delay (P < .04 vs. baseline) and 286.90 +/- 35 ms (P < .04 vs. baseline) at optimal AV and VV delay in those who underwent VV optimization. CONCLUSIONS: AV and VV optimization by echocardiography produces significant improvement in LV(E-dur) and RA(E-dur). Radial artery tonometry may provide a simple noninvasive method to assist in AV delay optimization.
Authors: José M Dizon; T Alexander Quinn; Santos E Cabreriza; Daniel Wang; Henry M Spotnitz; Kathleen Hickey; Hasan Garan Journal: Europace Date: 2010-06-04 Impact factor: 5.214
Authors: Christopher K Johnson; Santos E Cabreriza; Rana L Sahar; Alexander Rusanov; Daniel Y Wang; Bin Cheng; Mira S Gendy; T Alexander Quinn; Henry Michael Spotnitz Journal: ASAIO J Date: 2012 May-Jun Impact factor: 2.872