Non-Invasive Cardiac Output Measurement for CRT Optimization (NICaS-CRT)

1. Introduction

   Cardiac resynchronization therapy (CRT) is an efficient treatment in heart failure (HF) patients with left ventricular (LV) systolic dysfunction and wide QRS. It is associated with improved exercise capacity, quality of life and left ventricular ejection fraction, as well as reverse remodeling, mitral regurgitation reduction, and mortality reduction.

   Predicting response to CRT is important as 30% of patients have no or minimal clinical improvement following CRT. Several parameters have been shown to influence response following implantation. Some relate to patients' characteristics including underlying heart disease, comorbidities and arrhythmias, type and severity of conduction disorder, presence and degree of dyssynchrony, presence and extent of scar tissue and functional myocardial reserve. Others are associated with technical aspects, including electrical and anatomical positioning of LV lead, programming mode and percentage of effective bi-ventricular pacing.

   Optimization of the atrio-ventricular (AV) delay and inter-ventricular (VV) delays can be used for maximizing CRT benefit, but is not routinely recommended by current guidelines. Standard optimization is performed under echocardiography guidance - a time and resource consuming method. Other non-invasive methods, such as impedance cardiography, can be used for AV delay optimization.

2. Rationale for CRT optimization using NICaS

   The non-invasive cardiac system (NICaS) is a whole-body bioimpedance measurement method allowing real-time cardiac output (CO) assessment. It has been FDA approved for assisting in the diagnosis, monitoring and care management of patients with congestive heart failure as well as for cardiac pacemaker optimization. Clinical trials have shown its utility for the follow-up of outpatient monitoring chronic heart failure, for monitoring patients with heart failure and pulmonary hypertension.

   NICaS is sensitive enough for detecting real-time small changes in CO. Based on NICaS measured CO changes following AV and VV delays modifications, small series support its use for CRT optimization in a clinical setting, suggesting it may be associated with a reduction in non-responder rate.

3. Hypothesis

   We hypothesize that the use of NICaS for optimization of AV and VV delays in chronic (more than 6 months) CRT recipients may result in an added clinical and echocardiographic benefit.

4. Specific Aims

   1. Identify the CRT recipients who are prone to benefit following CRT optimization, by finding the predictors (clinical, ECG, echocardiographic, hemodynamic) for significant cardiac output improvement after NICaS guided CRT optimization
   2. Correlate the degree of cardiac output improvement (as measured by NICaS) after NICaS guided CRT optimization, with clinical and echocardiographic changes at 6 months

5. Timeline:

I. At Inclusion

I.A. Baseline assessment. Patients included in the study will benefit from the following at baseline assessment, performed in an outpatient setting:

1. Clinical evaluation:

   1. history;
   2. NYHA class; six-minute walk test (6MWT); Minnesota Living with Heart Failure questionnaire for the quality of life (QoL);
   3. status following CRT (responder/non-responder);
   4. physical evaluation;
   5. current medication

2. ECG

3. Device interrogation

4. Transthoracic echocardiography (including dyssynchrony parameters)

I.B. NICaS protocol for optimal AV and VV delays assessment. After baseline assessment is completed, patients will benefit from NICaS hemodynamic assessment and CRT programming according to NICaS guided optimal AV and VV delays. (for NICaS protocol for optimal AV and VV delays measurements - see Interventions)

I.C. After NICaS guided CRT programming, patients will perform a 6MWT

II. At 6 months follow-up. At 6 months, patients will benefit from the following evaluations:

1. Clinical: NYHA class, 6MWT, Minnesota Living with Heart Failure questionnaire for the quality of life, current medication
2. ECG
3. Device interrogation
4. Transthoracic echocardiography