Analysis of Different Device-Based Intrathoracic Impedance Vectors for Detection of Heart Failure Events (from the Detect Fluid Early from Intrathoracic Impedance Monitoring Study) - 21/08/14

Doi : 10.1016/j.amjcard.2014.07.048

E. Kevin Heist, MD, PhD ^a,^⁎ , John M. Herre, MD ^b, Philip F. Binkley, MD, MPH ^c, Adrian B. Van Bakel, MD, PhD ^d, James G. Porterfield, MD ^e, Linda M. Porterfield, PhD ^e, Fujian Qu, DSc ^f, Melanie Turkel, MS ^f, Behzad B. Pavri, MD ^g
for the
DEFEAT-PE Study Investigators
^a Cardiac Arrhythmia Service, Massachusetts General Hospital, Boston, Massachusetts
^b Eastern Virginia Medical and Sentara Norfolk General Hospital, Norfolk, Virginia
^c Division of Cardiovascular Medicine and Davis Heart and Lung Institute, The Ohio State University, Columbus, Ohio
^d Medical University of South Carolina, Charleston, South Carolina
^e Methodist University Hospital, Memphis, Tennessee
^f St. Jude Medical, Sylmar, California
^g Thomas Jefferson University School of Medicine, Philadelphia, Pennsylvania

^∗Corresponding author: Tel: (617) 726-4959; fax: (617) 726-3852.

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Abstract

Detect Fluid Early from Intrathoracic Impedance Monitoring (DEFEAT-PE) is a prospective, multicenter study of multiple intrathoracic impedance vectors to detect pulmonary congestion (PC) events. Changes in intrathoracic impedance between the right ventricular (RV) coil and device can (RVcoil→Can) of implantable cardioverter-defibrillators (ICDs) and cardiac resynchronization therapy ICDs (CRT-Ds) are used clinically for the detection of PC events, but other impedance vectors and algorithms have not been studied prospectively. An initial 75-patient study was used to derive optimal impedance vectors to detect PC events, with 2 vector combinations selected for prospective analysis in DEFEAT-PE (ICD vectors: RVring→Can + RVcoil→Can, detection threshold 13 days; CRT-D vectors: left ventricular ring→Can + RVcoil→Can, detection threshold 14 days). Impedance changes were considered true positive if detected <30 days before an adjudicated PC event. One hundred sixty-two patients were enrolled (80 with ICDs and 82 with CRT-Ds), all with ≥1 previous PC event. One hundred forty-four patients provided study data, with 214 patient-years of follow-up and 139 PC events. Sensitivity for PC events of the prespecified algorithms was as follows: ICD: sensitivity 32.3%, false-positive rate 1.28 per patient-year; CRT-D: sensitivity 32.4%, false-positive rate 1.66 per patient-year. An alternative algorithm, ultimately approved by the US Food and Drug Administration (RVring→Can + RVcoil→Can, detection threshold 14 days), resulted in (for all patients) sensitivity of 21.6% and a false-positive rate of 0.9 per patient-year. The CRT-D thoracic impedance vector algorithm selected in the derivation study was not superior to the ICD algorithm RVring→Can + RVcoil→Can when studied prospectively. In conclusion, to achieve an acceptably low false-positive rate, the intrathoracic impedance algorithms studied in DEFEAT-PE resulted in low sensitivity for the prediction of heart failure events.

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Highlights

•	Prediction of CHF on the basis of thoracic impedance was examined.
•	Impedance vectors from RV and LV leads were evaluated in ICD and CRT patients.
•	Algorithms producing low false-positive rates had low sensitivity to detect CHF.
•	Algorithms including LV and RV leads were not superior to RV lead–only algorithms.
•	An algorithm involving the RV lead and can was FDA approved on the basis of this study.